Fluid pump

The invention claimed is: 1 . A fluid pump for conveying a fluid comprising: a housing including a fluid inlet and a fluid outlet and a rotor, which is arranged rotatably about an axis of rotation within the housing for conveying fluid between the fluid inlet and the fluid outlet, the rotor having an inlet-side end extending towards the fluid inlet, an outlet-side end extending towards the fluid outlet, and an outer surface radial to the axis of rotation and cooperating with an inner surface of the housing to define a flow channel for conveying fluid between the rotor and the housing, the rotor being mounted in the housing by way of a mechanical bearing, wherein the mechanical bearing is arranged at the inlet-side end of the rotor, and where the mechanical bearing comprises at least a first bearing component associated with the housing in contact with at least a second bearing component associated with the rotor, and wherein within the flow channel a profile of a flow cross-section between the outer surface of the rotor and the inner surface of the housing, in the direction of the axis of rotation, has a local or regional flow cross-section minimum in the region of the mechanical bearing; wherein a maximum increase in the flow cross-section, in the direction of the axis of rotation, upstream of the local or regional flow cross-section minimum is greater than, or equal to, that downstream of the local or regional flow cross-section minimum. 2 . A fluid pump for conveying a fluid comprising: a housing including a fluid inlet and a fluid outlet and a rotor, which is arranged rotatably about an axis of rotation within the housing for conveying fluid from the fluid inlet to the fluid outlet, the rotor having an inlet-side end extending towards the fluid inlet and an outlet-side end extending towards the fluid outlet, the rotor being mounted in the housing by way of a mechanical bearing, wherein the mechanical bearing is arranged at the inlet-side end of the rotor, and where the mechanical bearing comprises at least a first bearing component associated with the housing in contact with at least a second bearing component associated with the rotor, wherein a profile of a flow cross-section between the rotor and the housing, in the direction of the axis of rotation, has a local or regional flow cross-section minimum in the region of the mechanical bearing, and wherein a maximum increase in the flow cross-section, in the direction of the axis of rotation, upstream of the local or regional flow cross-section minimum is greater than, or equal to, that downstream of the local or regional flow cross-section minimum. 3 . The fluid pump of claim 2 , wherein the local or regional flow cross-section minimum is located in the region of the first bearing component, in the region of the second bearing component, and/or in the region of the contact region. 4 . The fluid pump of claim 2 , wherein the housing comprises an inner wall that delimits a fluid region and is closed in a circumferential direction around the axis of rotation, and the local or regional flow cross-section minimum results from a profile of a wall diameter of the inner wall, in the direction of the axis of rotation, having a local or regional minimum in the region of the mechanical bearing. 5 . The fluid pump of claim 3 , wherein the profile of the wall diameter has a local or regional minimum in the region of the first bearing component, in the region of the second bearing component and/or in the region of the contact region. 6 . The fluid pump of claim 3 , wherein the local flow cross-section minimum results from a profile of a bearing diameter of the mechanical bearing having a local or regional maximum in the direction of the axis of rotation. 7 . The fluid pump of claim 6 , wherein the profile of the bearing diameter has a local or regional maximum in the region of the first bearing component, in the region of the second bearing component and/or in the region of the contact region. 8 . The fluid pump of claim 2 , wherein the flow cross-section is reduced in the local or regional flow cross-section minimum by ≥10% and/or ≤50% compared to a flow cross-section in a region adjoining the bearing region upstream and/or downstream. 9 . The fluid pump of claim 2 , wherein the flow cross-section, in the direction of the axis of rotation, increases by ≥2% of the flow cross-section minimum per mm and/or ≤30% of the flow cross-section minimum per mm upstream of the flow cross-section minimum, and increases by ≤20% of the flow cross-section minimum per mm downstream of the flow cross-section minimum. 10 . The fluid pump of claim 2 , wherein the flow cross-section, in the direction of the axis of rotation, increases by ≥2% of the flow cross-section minimum per mm and/or ≤30% of the flow cross-section minimum per mm upstream and/or downstream of the flow cross-section minimum. 11 . The fluid pump of claim 3 , wherein the local or regional flow cross-section minimum is a regional flow cross-section minimum and is located in the region of the contact region as well as downstream of the contact region. 12 . The fluid pump of claim 2 , wherein local or regional flow cross-section minimum is designed in such a way that a wall shear stress has a local maximum or is maximal in the region of the mechanical bearing. 13 . The fluid pump of claim 3 , wherein the first and/or the second bearing components comprise, or consist of, a material having a low coefficient of friction and/or a material having a high coefficient of thermal conductivity selected from a ceramic material, sintered metal and/or diamond. 14 . The fluid pump of claim 2 , wherein the local or regional flow cross-section minimum is located at the same axial height as the first bearing component. 15 . The fluid pump of claim 14 , wherein the flow cross-section is reduced in the local or regional flow cross-section minimum by >10% compared to a flow cross-section in a region adjoining the bearing region upstream. 16 . The fluid pump of claim 2 , wherein the housing comprises an inner wall that delimits a fluid region and is closed in a circumferential direction around the axis of rotation, and the local or regional flow cross-section minimum results from the inner wall, in the region of the mechanical bearing, comprising a radial constriction. 17 . The fluid pump of claim 16 , wherein the flow cross-section minimum is a local flow cross-section minimum, and the flow cross-section increases in the direction of the axis of rotation, downstream of the flow cross-section minimum. 18 . The fluid pump of claim 14 , wherein the flow cross-section minimum has a regional flow cross-section minimum.