Patent Number: 062298771
Section: claims

1. A radiation image recording and read-out method, comprising the steps of: i) locating a radiation source, which produces radiation, on one side of an object,  ii) locating two-dimensional image read-out means on the other side of the object, said two-dimensional image read-out means comprising stripe-shaped electrodes for reading latent image charges, which carry image information, and  iii) performing an operation for recording and reading out a radiation image of the object,  wherein a grid plate is located between the object and said two-dimensional image read-out means, said grid plate guiding only the radiation, which comes from a specific direction, to said two-dimensional image read-out means, and  the operation for recording and reading out the radiation image of the object is performed in this state.  i) a radiation source, which produces radiation,  ii) two-dimensional image read-out means comprising stripe-shaped electrodes for reading latent image charges, which carry image information, and  iii) a grid plate, which is located between said radiation source and said two-dimensional image read-out means, said grid plate guiding only the radiation, which comes from a specific direction, to said two-dimensional image read-out means.  said grid plate is constituted of radiation absorbing substance regions and radiation-permeable substance regions, which are arrayed alternately at a predetermined grid pitch so as to stand side by side in the direction approximately normal to the longitudinal direction of each stripe-shaped electrode, and  a spatial frequency of the pitch of said stripe-shaped electrodes is at least two times as high as a spatial frequency of the grid pitch.  said grid plate is constituted of radiation absorbing substance regions and radiation-permeable substance regions, which are arrayed alternately at a predetermined grid pitch so as to stand side by side in the longitudinal direction of each stripe-shaped electrode, and  a spatial frequency of a sampling pitch, at which the latent image charges are read with scanning in the longitudinal direction of each stripe-shaped electrode, is at least two times as high as a spatial frequency of the grid pitch.  said grid plate is constituted of radiation absorbing substance regions and radiation-permeable substance regions, which are arrayed alternately at a predetermined grid pitch so as to stand side by side in the direction approximately normal to the longitudinal direction of each stripe-shaped electrode, and  a difference between a spatial frequency of the pitch of said stripe-shaped electrodes and a spatial frequency of the grid pitch is at least 1 cycle/mm.  said grid plate is constituted of radiation absorbing substance regions and radiation-permeable substance regions, which are arrayed alternately at a predetermined grid pitch so as to stand side by side in the longitudinal direction of each stripe-shaped electrode, and  a difference between a spatial frequency of a sampling pitch, at which the latent image charges are read with scanning in the longitudinal direction of each stripe-shaped electrode, and a spatial frequency of the grid pitch is at least 1 cycle/mm.  i) locating a radiation source, which produces radiation, on one side of an object,  ii) locating two-dimensional image read-out means and a radio-conductive material, which is formed on said two-dimensional image read-out means, on the other side of the object, said two-dimensional image read-out means comprising an insulating substrate and a plurality of charge collecting electrodes, which are formed in a two-dimensional pattern on said insulating substrate and each of which corresponds to a single pixel, said radio-conductive material generating electric charges carrying image information when it is exposed to radiation carrying the image information, and  iii) performing an operation for recording and reading out a radiation image of the object,  wherein a grid plate is located between the object and said radio-conductive material, said grid plate guiding only the radiation, which comes from a specific direction, to said radio-conductive material, and  the operation for recording and reading out the radiation image of the object is performed in this state.  i) a radiation source, which produces radiation,  ii) two-dimensional image read-out means comprising an insulating substrate and a plurality of charge collecting electrodes, which are formed in a two-dimensional pattern on said insulating substrate and each of which corresponds to a single pixel,  iii) a radio-conductive material, which is formed on said two-dimensional image read-out means, said radio-conductive material generating electric charges carrying image information when it is exposed to radiation carrying the image information, and  iv) a grid plate, which is located between said radiation source and said radio-conductive material, said grid plate guiding only the radiation, which comes from a specific direction, to said radio-conductive material.  said grid plate is constituted of radiation absorbing substance regions and radiation-permeable substance regions, which are arrayed alternately at a predetermined grid pitch so as to stand side by side in at least either one of the X direction and the Y direction, and  a spatial frequency of said charge collecting electrodes in the grid array direction is at least two times as high as a spatial frequency of the grid pitch.  said grid plate is constituted of radiation absorbing substance regions and radiation-permeable substance regions, which are arrayed alternately at a predetermined grid pitch so as to stand side by side in at least either one of the X direction and the Y direction, and  a difference between a spatial frequency of said charge collecting electrodes in the grid array direction and a spatial frequency of the grid pitch is at least 1 cycle/mm.  i) a radiation source, which produces radiation,  ii) two-dimensional image read-out means comprising an insulating substrate and a plurality of photoelectric conversion devices, which are formed in a two-dimensional pattern on said insulating substrate and each of which corresponds to a single pixel,  iii) a fluorescent material, which is formed on said two-dimensional image read-out means, said fluorescent material converting radiation carrying image information into visible light carrying the image information when it is exposed to the radiation carrying the image information, and  iv) a grid plate, which is located between said radiation source and said fluorescent material, said grid plate guiding only the radiation, which comes from a specific direction, to said fluorescent material,  wherein said photoelectric conversion devices of said two-dimensional image read-out means are arrayed at a predetermined pitch in an X direction and at a predetermined pitch in a Y direction,  said grid plate is constituted of radiation absorbing substance regions and radiation-permeable substance regions, which are arrayed alternately at a predetermined grid pitch so as to stand side by side in at least either one of the X direction and the Y direction, and  a spatial frequency of said photoelectric conversion devices in the grid array direction is at least two times as high as a spatial frequency of the grid pitch.  i) a radiation source, which produces radiation,  ii) two-dimensional image read-out means comprising an insulating substrate and a plurality of photoelectric conversion devices, which are formed in a two-dimensional pattern on said insulating substrate and each of which corresponds to a single pixel,  iii) a fluorescent material, which is formed on said two-dimensional image read-out means, said fluorescent material converting radiation carrying image information into visible light carrying the image information when it is exposed to the radiation carrying the image information, and  iv) a grid plate, which is located between said radiation source and said fluorescent material, said grid plate guiding only the radiation, which comes from a specific direction, to said fluorescent material,  wherein said photoelectric conversion devices of said two-dimensional image read-out means are arrayed at a predetermined pitch in an X direction and at a predetermined pitch in a Y direction,  said grid plate is constituted of radiation absorbing substance regions and radiation-permeable substance regions, which are arrayed alternately at a predetermined grid pitch so as to stand side by side in at least either one of the X direction and the Y direction, and  a difference between a spatial frequency of said photoelectric conversion devices in the grid array direction and a spatial frequency of the grid pitch is at least 1 cycle/mm.  a) a first thin metal film layer, which acts as a lower electrode,  b) an amorphous silicon nitride insulation layer (a-SiN.sub.x), which blocks passage of electrons and holes,  c) a hydrogenated amorphous silicon photoelectric conversion layer (a-Si:H),  d) an injection blocking layer selected from the group consisting of an n-type injection blocking layer, which blocks injection of hole carriers, and a p-type injection blocking layer, which blocks injection of electron carriers, and  e) a layer selected from the group consisting of a transparent electrode layer, which acts as an upper electrode, and a second thin metal film layer, which is formed on a portion of said injection blocking layer,  the layers being overlaid in this order on said insulating substrate.  said image processing means performs processing for suppressing the signal components on the digital image signal.  said image processing means performs processing for suppressing the signal components on the digital image signal.  said image processing means performs processing for suppressing the signal components on the digital image signal.  said image processing means performs processing for suppressing the signal components on the digital image signal. 2. A radiation image recording and read-out apparatus, comprising: 3. An apparatus as defined in claim 2 wherein said stripe-shaped electrodes of said two-dimensional image read-out means are arrayed at a predetermined pitch so as to stand side by side in a direction, which is approximately normal to a longitudinal direction of each stripe-shaped electrode, 4. An apparatus as defined in claim 2 wherein said stripe-shaped electrodes of said two-dimensional image read-out means are arrayed at a predetermined pitch so as to stand side by side in a direction, which is approximately normal to a longitudinal direction of each stripe-shaped electrode, 5. An apparatus as defined in claim 2 wherein said stripe-shaped electrodes of said two-dimensional image read-out means are arrayed at a predetermined pitch so as to stand side by side in a direction, which is approximately normal to a longitudinal direction of each stripe-shaped electrode, 6. An apparatus as defined in claim 2 wherein said stripe-shaped electrodes of said two-dimensional image read-out means are arrayed at a predetermined pitch so as to stand side by side in a direction, which is approximately normal to a longitudinal direction of each stripe-shaped electrode, 7. A radiation image recording and read-out method, comprising the steps of: 8. A radiation image recording and read-out apparatus, comprising: 9. An apparatus as defined in claim 8 wherein said charge collecting electrodes of said two-dimensional image read-out means are arrayed at a predetermined pitch in an X direction and at a predetermined pitch in a Y direction, 10. An apparatus as defined in claim 8 wherein said charge collecting electrodes of said two-dimensional image read-out means are arrayed at a predetermined pitch in an X direction and at a predetermined pitch in a Y direction, 11. A radiation image recording and read-out apparatus, comprising: 12. A radiation image recording and read-out apparatus, comprising: 13. An apparatus as defined in claim 11 or 12 wherein each of said photoelectric conversion devices comprises: 14. An apparatus as defined in claim 2, 3, 4, 5, 6, 8, 9, 10, 11 or 12 wherein the apparatus is provided with first image processing means for suppressing signal components, which are contained in an image signal having been detected by said two-dimensional image read-out means and which carry a spatial frequency of a grid pitch. 15. An apparatus as defined in claim 13 wherein the apparatus is provided with first image processing means for suppressing signal components, which are contained in an image signal having been detected by said two-dimensional image read-out means and which carry a spatial frequency of a grid pitch. 16. An apparatus as defined in claim 2, 3, 5, 6, 8, 10, or 12 wherein the apparatus is provided with second image processing means for suppressing signal components, which are contained in an image signal having been detected by said two-dimensional image read-out means and which carry a moire frequency occurring due to the grid. 17. An apparatus as defined in claim 13 wherein the apparatus is provided with second image processing means for suppressing signal components, which are contained in an image signal having been detected by said two-dimensional image read-out means and which carry a moire frequency occurring due to the grid. 18. An apparatus as defined in claim 14 wherein the apparatus further comprises an analog-to-digital converter for converting the image signal, which has been detected by said two-dimensional image read-out means, into a digital image signal, and 19. An apparatus as defined in claim 15 wherein the apparatus further comprises an analog-to-digital converter for converting the image signal, which has been detected by said two-dimensional image read-out means, into a digital image signal, and 20. An apparatus as defined in claim 16 wherein the apparatus further comprises an analog-to-digital converter for converting the image signal, which has been detected by said two-dimensional image read-out means, into a digital image signal, and 21. An apparatus as defined in claim 17 wherein the apparatus further comprises an analog-to-digital converter for converting the image signal, which has been detected by said two-dimensional image read-out means, into a digital image signal, and