Weigh-in-motion force transducer and housing profile for such W-I-M force transducer

What is claimed is: 1. A Weigh-in-motion force transducer comprising: a housing profile that defines a tubular part, which defines an interior forming a cavity; a piezoelectric measuring arrangement that generates electric polarization charges under the impact of a reaction force that acts via the housing profile along a force introduction axis, wherein the piezoelectric measuring arrangement is mounted within the cavity under mechanical prestress along the force introduction axis; wherein the tubular part is defined by a configuration that expands along the force introduction axis by an applied mounting force that acts on the tubular part along a mounting force axis, wherein the configuration of the tubular part is elliptical in shape in a cross-sectional plane defined by the force introduction axis and the mounting force axis and has a major semiaxis extending along the mounting force axis and a minor semiaxis extending along the force introduction axis, and wherein the major semiaxis is longer than the minor semiaxis. 2. The WIM force transducer according to claim 1 , wherein the tubular part has an outer surface and a center point, which outer surface is formed elliptically away from the center point. 3. The WIM force transducer according to claim 2 , wherein the tubular part includes a mounting area and an inner surface, which mounting area is on the mounting force axis; and wherein the mounting area and the inner surface is formed to be concave towards the center point. 4. The WIM force transducer according to claim 3 , wherein the mounting area extends on the inner surface between a first turning point and a second turning point; and on the inner surface and the mounting area has a constant concave reinforcement radius. 5. The WIM force transducer according to claim 3 , wherein the mounting area extends along a radial axis over a mounting area angle. 6. The WIM force transducer according to claim 3 , wherein the mounting area extends along the force introduction axis over a reinforcement height. 7. The WIM force transducer according to claim 2 , wherein the tubular part has a plurality of wall sections; wherein each wall section has a respective outer surface that is formed elliptically away from the center point, wherein each wall section has a respective inner surface that is formed elliptically away from the center point; and wherein each of the wall sections defines a respective wall thickness that is essentially constant. 8. The WIM force transducer according to claim 7 , wherein each respective wall section defines a respective wall thickness; wherein each respective wall thickness in each respective wall section in the mounting area is a reinforced wall thickness; and wherein the thickness of each respective reinforced wall thickness is greater than the thickness of each respective wall thickness that is not reinforced. 9. The WIM force transducer according to claim 7 , wherein a mounting area extends on the inner surface between a first turning point and a second turning point; and wherein at the first turning point the mounting area is continuous with a wall section. 10. The WIM force transducer according to claim 1 , wherein along the force introduction axis the cavity is defined by a height that is larger by a vertical oversize as compared to the dimensions of the piezoelectric measuring arrangement that is mounted within the cavity. 11. The WIM force transducer according to claim 10 , wherein along the force introduction axis the cavity is defined by a height that is delimited by a pair of inner force introduction surfaces; wherein the inner force introduction surfaces have a vertical distance from each other; wherein the piezoelectric measuring arrangement has a vertical height along the force introduction axis; and wherein a difference between the vertical distance and the vertical height is the vertical oversize. 12. The WIM force transducer according to claim 10 , wherein the minor semiaxis is configured for an expansion to an expanded minor semiaxis along the force introduction axis for mounting the piezoelectric measuring arrangement in the cavity; which expansion is at least as large as the vertical oversize and manufacturing tolerances of the tubular part and the piezoelectric measuring arrangement along the force introduction axis. 13. The WIM force transducer according to claim 1 , wherein the tubular part is configured with an expanded minor semiaxis for accommodating the piezoelectric measuring arrangement mounted in the cavity. 14. The WIM force transducer according to claim 13 , wherein along the force introduction axis the cavity is defined by a height that is larger by a vertical oversize as compared to the dimensions of the piezoelectric measuring arrangement that is mounted within the cavity; wherein the expanded minor semiaxis with the mounted piezoelectric measuring arrangement can be deformed to a residually expanded minor semiaxis having an expansion that is of the same amount as the vertical oversize and manufacturing tolerances of the tubular part and the piezoelectric measuring arrangement along the force introduction axis. 15. The WM force transducer according to claim 14 , wherein the tubular part is configured so that the expanded minor semiaxis with the mounted piezoelectric measuring arrangement can be deformed to the residually expanded minor semiaxis by releasing a mounting force acting along a force introduction axis; and wherein the tubular part is configured so that the residually expanded minor semiaxis generates the mechanical prestress. 16. A housing profile for a Weigh-in-motion force transducer, comprising: a housing profile that defines a tubular part, which defines an interior forming a cavity; a piezoelectric measuring arrangement that generates electric polarization charges under the impact of a reaction force that acts via the housing profile along a force introduction axis, wherein the piezoelectric measuring arrangement is mounted within the cavity under mechanical prestress along the force introduction axis; wherein the tubular part is defined by a configuration that expands along the force introduction axis by an applied mounting force that acts on the tubular part along a mounting force axis, wherein the configuration of the tubular part is elliptical in shape in a cross-sectional plane defined by the force introduction axis and the mounting force axis and has a major semiaxis extending along the mounting force axis and a minor semiaxis extending along the force introduction axis; and wherein the major semiaxis is at least 5% larger than the minor semiaxis.