Patent Number: 
Section: claims

1. An X-ray differential phase contrast imaging device, comprising:an X-ray source for generating an X-ray beam;a source grating (G0) for generating a coherent X-ray beam from a non-coherent X-ray source (20);a collimator comprising slits for splitting the coherent X-ray beam into a plurality of fan-shaped X-ray beams for passing through an object;a phase grating (G1) for generating an interference pattern and an absorber grating (G2) for generating a Moiré pattern from the interference pattern arranged after the object;a line detector comprising detector lines for detecting the Moiré pattern generated by the phase grating (G1) and the absorber grating (G2) from the fan-shaped X-ray beams (28) passing through the object;wherein the X-ray source, source grating (G0), collimator, phase grating (G1), absorber grating (G2) and line detector are fixed to a common gantry and are movable with respect to the object, such that a number of interference patterns from different positions of the gantry are detectable for reconstructing a differential phase image of the object;wherein groups of grating lines and transparent areas (38) alternate with respect to each other in a direction perpendicular to the direction of the detector lines;wherein at least one grating (G0, G1, G2) of the source grating, the phase grating and the absorber grating comprises groups of grating lines and transparent areas between the groups of grating lines, and is movable with respect to the gantry, such thatin a first position of the source grating (G0) the X-ray beams pass through the grating lines and subsequently pass through the slits of the collimator and in a second position of the source grating (G0) the X-ray beams pass through the transparent areas and subsequently pass through the slits of the collimator, orin a first position at least one of the phase grating (G1) or the absorber grating (G2) the fan-shaped X-ray beams pass through the grating lines, and in a second position at least one of the phase grating (G1) or the absorber grating (G2) the fan-shaped X-ray beams pass through the transparent areas. 2. The imaging device of claim 1,wherein the groups of grating lines are equidistant and the transparent areas are equidistant. 3. The imaging device of claim 1,wherein the grating (G0, G1, G2) comprises a substrate transparent for X-rays and the transparent areas comprises areas on the substrate without metallization. 4. The imaging device of claim 3,wherein the grating lines are metal lines on the substrate; and/orwherein the grating lines are metal-filled trenches in the substrate; and/ orwherein the grating lines are trenches in the substrate. 5. The imaging device of claims claim 1, wherein the transparent areas (38) comprises holes in a substrate of the grating. 6. The imaging device of claim 1, further comprising:a motor for moving the grating (G1, G2) between the first position and the second position; anda controller for controlling the movement. 7. The imaging device claim 1,wherein the first position of the grating (G1, G2) is determined by a mechanical stopper. 8. The imaging device claim 1,wherein the first position of the grating (G1, G2) is determined by a position sensor. 9. The imaging device claim 1, further comprising:rails for guiding the grating. 10. The imaging device claim 1,wherein only the absorber grating (G2) has the transparent areas. 11. The imaging device claim 1,wherein the phase grating (G1) and the absorber grating (G2) have the transparent areas. 12. The imaging device of claim 11,wherein the phase grating (G1) and the absorber grating (G2) are movable independently from each other between the first position and the second position; and/orwherein the phase grating (G1) and the absorber grating (G2) are fixedly connected with each other and are movable together between the first position and the second position. 13. The imaging device claim 1, further comprising:a hinge for removing the source grating (G0) from the X-ray beam. 14. A method for acquiring differential phase image data and attenuation image data with the same device, the method comprising:moving a grating (G0, G1, G2) selected from a source grating, a phase grating and an absorber grating of the device in a first position, such that fan-shaped X-ray beams generated by a collimator pass through groups of grating lines on the grating (G0, G1, G2);acquiring differential phase image data by moving a gantry with the source grating (G0), phase grating (G1) and absorber grating (G2) and a line detector with respect to an object and by detecting X-rays passing through the object, the source grating (G0), phase grating (G1) and the absorber grating (G2) at a plurality of positions of the gantry;moving the grating (G0, G1, G2) in a second position, such that the fan-shaped X-ray beams pass through transparent areas on the grating (G0, G1, G2); andacquiring attenuation image data by moving the gantry with respect to the object and by detecting X-rays passing through the object at a plurality of positions of the gantrywherein in a first position of the source grating (G0) the X-ray beams pass through the grating lines and subsequently pass through the slits of the collimator and in a second position of the source grating (G0) the X-ray beams pass through the transparent areas and subsequently pass through the slits of the collimator, orin a first position at least one of the phase grating (G1) or the absorber grating (G2) the fan-shaped X-ray beams pass through the grating lines, and in a second position at least one of the phase grating (G1) or the absorber grating (G2) the fan-shaped X-ray beams pass through the transparent areas. 15. The method of claim 14, further comprising:calibrating the line detector, when the absorber grating (G2) and the phase grating (G1) are in the second position; andcalibrating the phase grating (G1) and the absorber grating (G2), when the phase grating (G1) and the absorber grating (G2) are in the first position and the source grating (G0) is in the second position.