Patent Number: 
Section: claims

1. An X-ray imaging apparatus, comprising:a source for generating X-ray radiation emitting a polychromatic spectrum of X-ray energies;an object receiving space for arranging an object of interest for X-ray imaging;an X-ray collimator arrangement; andan X-ray mirror arrangement;wherein the X-ray collimator arrangement comprises at least a pre-collimator arranged between the source and the object receiving space for providing collimated X-ray radiation to the object receiving space;wherein the X-ray mirror arrangement is arranged between the source and the pre-collimator;wherein the X-ray mirror arrangement comprises a set of two mirrors for guiding X-ray radiation of the source by providing total reflection of the whole polychromatic spectrum of X-ray energies of a part of the X-ray radiation in order to deflect the part of the X-ray radiation towards the pre-collimator such that in the region of the object receiving space enhanced radiation is provided in form of unreflected primary X-ray radiation in combination with secondary X-ray radiation by total reflection; andwherein the mirrors of the set of two mirrors are facing one another with an angle of spread (θm) larger than zero, such that the set of mirrors providing an X-ray entrance having an entrance width and an X-ray exit having an exit width, which is smaller than the entrance width. 2. The apparatus according to claim 1, wherein the primary X-ray radiation forms a primary beam cone between the source and the pre-collimator,wherein the mirrors of the set of mirrors abuts outside on the primary beam cone, andwherein the angle of spread corresponds to a cone angle (θk) of the primary beam cone with a maximum deviation to the cone angle of 10%. 3. The apparatus according to claim 2, wherein a length LM of each of the mirrors of the set of mirrors is arranged, such that the inequalityLM≤LMmax=LW/(Θc2−Θm)holds, wherein:LW is the width of the exit of the set of mirrors,Θc2 is the critical angle of reflection at a mirror of the set of mirrors,Θm is the angle of spread of the mirrors of the set of mirrors. 4. The apparatus to claim 1, wherein the exit of the set of mirrors abuts to an aperture of the pre-collimator. 5. The apparatus according to claim 1, wherein the aperture of the pre-collimator is formed by the set of mirrors. 6. The apparatus according to claim 1, wherein the set of mirrors are arranged such that for the part of the X-ray radiation of the source to be reflected at the set of mirrors, a maximum of one or two total reflections at the mirrors of the set of mirrors occur. 7. The apparatus according to claim 1, wherein the pre-collimator comprises at least two apertures; andwherein, for each aperture of the pre-collimator, the mirror arrangement comprises an associated set of mirrors. 8. The apparatus according to claim 1, wherein the collimator arrangement further comprises a post-collimator; andwherein the object receiving space is arranged between the pre-collimator and the post collimator. 9. The apparatus according to claim 1, wherein each mirror of the sets of mirrors comprises a substrate with a coating layer for providing the total reflection; andwherein, between the coating layer and the substrate, a boundary is provided that is configured to reduce scatter radiation from incoming radiation that is not reflected but passes a mirror surface and enters the coating layer. 10. The apparatus according to claim 9, wherein, between the coating layer and the substrate, an uneven interface region is provided as the boundary. 11. The apparatus according to claim 10, wherein the interface has a randomly rough structured surface profile. 12. The apparatus according to claim 10, wherein the interface has a periodical profile with a periodical height between 0.05 mm and 1.5 mm, and a period between 0.5 mm and 5 mm. 13. The apparatus according to claim 12, wherein a thickness of the coating layer is between 10 nm and 25 nm. 14. An X-ray imaging system, comprising:an apparatus comprising:a source for generating X-ray radiation emitting a polychromatic spectrum of X-ray energies;an object receiving space for arranging an object of interest for X-ray imaging;an X-ray collimator arrangement; andan X-ray mirror arrangement;wherein the X-ray collimator arrangement comprises at least a pre-collimator arranged between the source and the object receiving space for providing collimated X-ray radiation to the object receiving space;wherein the X-ray mirror arrangement is arranged between the source and the pre-collimator;wherein the X-ray mirror arrangement comprises a set of two mirrors for guiding X-ray radiation of the source by providing total reflection of the whole polychromatic spectrum of X-ray energies of a part of the X-ray radiation in order to deflect the part of the X-ray radiation towards the pre-collimator such that in the region of the object receiving space enhanced radiation is provided in form of unreflected primary X-ray radiation in combination with secondary X-ray radiation by total reflection; andwherein the mirrors of the set of two mirrors are facing one another with an angle of spread (θm) larger than zero, such that the set of mirrors providing an X-ray entrance having an entrance width and an X-ray exit having an exit width, which is smaller than the entrance width;a detector for detecting X-ray radiation passing the object receiving space;an imaging processing unit; andan image data output unit;wherein the imaging processing unit is configured to receive signals from the detector; and to compute image data of an object based on the signals; andwherein the image data output unit is configured to provide the image data for further purpose. 15. An X-ray imaging system according to claim 14, further comprising:a mounting arrangement for mechanically connecting the source, the mirror arrangement, the collimator arrangement and the detector,an actuator coupled to the mounting arrangement to displace the mounting arrangement, anda control unit to control the actuator,wherein the control unit is configured to receive signals from the detector and to compute a control signal based on the received signals from the detector.