Patent Number: 050330730
Section: claims

1. A system for radiographically inspecting a predetermined area of relatively stationary object positioned at a selected location, comprising: a source of radiation operative to transmit along a radiation path toward the selected location a fixed position radiation beam having a cross-sectional area at least corresponding to the predetermined inspection area;  detection means, having a detection area at least corresponding to the predetermined inspection area disposed in a fixed position in the radiation path in alignment with the fixed position radiation beam;  scanning point selection means, disposed in the radiation path between the radiation source and detection means, for sequentially selecting and transmitting a plurality of selected portions of the cross-sectional area of the fixed position radiation beam striking in sequence a corresponding plurality of portions of the detection area of the detection means in both the length and width dimension, each said selected portion of the cross-sectional area of the fixed position radiation beam corresponding to a pencil beam of radiation, the selected plurality of portions of the cross-sectional area of the radiation beam and the corresponding portions of the detection means, each having both a width dimension and a length dimension substantially greater than the cross-sectional area of each pencil beat at the selected location,  said detection means being responsive to each said selected portion of the fixed position radiation beam striking a corresponding portion of the detecting area for generating signals corresponding to radiation interactive with a corresponding portion of the predetermined inspection area of an object at the selected location;  position encoder means responsive to said scanning point selection means for determining the position of each selected portion of the fixed position radiation beam;  data processing means responsive to said position encoder means and said detecting means for processing the signals generated by the detected means; and  display means governed by said data processing means for generating a radiographic image of the predetermined area of the object.  a first rotating disk having a spirally-shaped aperture, disposed in the radiation path between the radiation source and the detection means, for sequentially selecting and transmitting spirally-shaped portions of the cross-sectional area of the fixed position radiation beam along the path in the direction toward the selected location; and  a second rotating disk having an opposite spirally-shaped aperture, disposed in the radiation path in alignment with said first rotating disk between said first rotating disk and the detecting means, for sequentially selecting from said spirally-shaped portions, and for transmitting to the selected location, said selected portions of cross-sectional area each corresponding to a said pencil beam of radiation.  means for selecting the intensity of the radiation source in accordance with the selected element.  a first rotating disk having a spirally-shaped aperture, disposed in the radiation path between the radiation source and the detection means, for sequentially selecting and transmitting spirally-shaped portions of the cross-sectional area of the fixed position radiation beam along the path in the direction toward the selected location; and  a second rotating disk having an opposite spirally-shaped aperture, disposed in the radiation path in alignment with said first rotating disk between said first rotating disk and the detecting means, for sequentially selecting from said spirally-shaped portions, and for transmitting to the selected location, said selected portions of cross-sectional area each corresponding to a said pencil beam of radiation.  transmitting a fixed position radiation beam having a cross-sectional area at least corresponding to the predetermined inspection area along a radiation path in a direction toward the selected location;  selecting sequentially a plurality of portions from the cross-sectional area of the fixed position radiation beam and transmitting the selected portions along the radiation path to the selected location, each said selected portion of the cross-sectional area of the fixed position radiation beam corresponding to a pencil beam of radiation, said plurality of portions having both a length and width dimension substantially greater than the cross-sectional area of each pencil beam;  detecting each of the selected portions of the fixed position radiation beam striking corresponding portions of the predetermined inspection area of an object at the plurality of selected locations and generating signals in response to the radiation striking the corresponding portions said plurality of locations having both a length and width dimensions substantially greater than the cross-sectional area of each pencil beam;  determining the position of each selected portion of the fixed position radiation beam;  processing the signals generated in response to the radiation striking the corresponding portions; and  generating a radiographic image of the predetermined area of the object.  sequentially selecting and transmitting selected spirally-shaped portions of the cross-sectional area of the fixed position radiation beam along the radiation path in the direction toward the selected location; and  sequentially selecting from said spirally-shaped portions, and transmitting to the selected location portions of cross-sectional area each corresponding to a said pencil beam of radiation.  a source of radiation operative to transmit along a radiation path, toward the selected location, a fixed radiation beam of a selected energy intensity having a cross-sectional area at least corresponding to the predetermined inspection area;  detection means, having a detection area at least corresponding to the predetermined inspection area, disposed in the radiation path in alignment with the fixed radiation beam;  scanning point selection means including a first rotatable disk having a spirally-shaped aperture, disposed in the radiation path between the radiation source and the detection means, said disk being rotatable a distance corresponding to a width of the aperture at the end of a predetermined time period for sequentially selecting and transmitting spirally-shaped portions of the cross-sectional area of the fixed radiation beam along the path in the direction toward the selected locations; and  a second rotatable disk having an opposite spirally-shaped aperture disposed in the radiation path in alignment with said first rotatable disk between said first rotatable disk and the detection means, and being completely rotatable during the predetermined time period for sequentially selecting from said spirally-shaped portions and for transmitting to the selected location, said selected portions of cross-sectional area each corresponding to a said pencil beam of radiation, said time period being pre-selected in accordance with the selected energy intensity;  said detection means being responsive to each said selected portion of the fixed radiation beam striking a corresponding portion of the detecting area for generating signals corresponding to radiation interactive with a corresponding portion of the predetermined inspection area of an object at the selected location;  position encoder means responsive to said scanning point selected means for determining the position of each selected portion of the fixed radiation beam;  data processing means responsive to said position encoder means and said detection means for processing the signals generated by the detection means; and  display means governed by said data processing means for generating a radiographic image of the predetermined area of the object.  means for selecting the intensity of the radiation source in accordance with the selected element.  a source of radiation operative to transmit along a radiation path, toward the selected location, a fixed radiation beam having a cross-sectional area at least corresponding to the predetermined inspection area;  detection means, having a detection area at least corresponding to the predetermined inspection area, disposed in the radiation path in alignment with the fixed radiation beam;  scanning point selection means including a first disk having an elongate aperture, disposed in the radiation path between the radiation source and detection means, said first disk being rotatable at the end of a predetermined time period, a distance corresponding to a width of the elongate aperture, and a second disk having an elongate aperture with a predetermined orientation relative to the first disk, said second disk being rotatable completely during the predetermined time period, for sequentially selecting and transmitting selected portions of the cross-section area of the fixed radiation beam striking in sequence corresponding portions of the detection area of the detection means, each said selected portion of the cross-section area of the fixed radiation beam corresponding to a pencil beam of radiation,  said detection means being responsive to each said selected portion of the first radiation beam striking a corresponding portion of the detecting area for generating signals corresponding to radiation interactive with a corresponding portion of the predetermined inspection area of an object at the selected location;  position encoder means responsive to said scanning point selection means for determining the position of each selected portion of the first radiation beam;  data processing means responsive to said position encoder means and said detection means for processing the signals generated by the detection means; and  display means governed by said data processing means for generating a radiographic image of the predetermined area of the object.  means for selecting the intensity of the radiation source in accordance with the selected element.  transmitting a radiation beam along a radiation path in a first direction toward the selected inspecting location, the beam having a cross-sectional area corresponding at least to the predetermined area of the inspecting location;  sequentially selecting a plurality of portions of the cross-sectional area of beam of radiation and transmitting the selected portions to the selected location, each said selected portion of the cross-sectional area of the fixed radiation beam corresponding to a pencil beam of radiation, and the plurality of portions of the cross-sectional area of the radiation beam having both a length and width dimension substantially greater than the pencil beam;  backscattering radiation in a second direction along the radiation path, opposite the first direction, through the object at the selected location;  detecting each of the plurality of selected portions of the first radiation travelling through an object at the inspecting location and backscattered in the second direction, and detecting second radiation interacting with the object and backscattered in the second direction, the plurality of portions of the inspection area having both a length and width dimension greater than one pencil beam;  generating signals in response to the detected radiation; and  processing the response signals for the sequentially selected area portions of the inspecting location to obtain a radiographic representation of the object at the inspecting location. 2. The system of claim 1 further comprising filtering means fixedly disposed in the radiation path between the radiation source and the scanning point selection means for determining the identity of at least a grouping of atomic elements. 3. The system of claim 1 wherein the scanning point selection means comprises: 4. The system of claim 2 wherein the filtering means comprises a fixed member composed of a selected atomic element having an area corresponding to at least the total radiation beam area; and 5. The system of claim 3, wherein said detection means includes a detection device wherein said radiation source and the detection device are disposed with the selected location therebetween. 6. The system of claim 3, wherein said detection means includes a defection device disposed in the radiation path between said radiation source and the selected location. 7. The system, of claim 3, wherein said detection means comprises a first detector device and a second detector device responsive to each of the selected portions of the fixed position radiation beam, said first detector device being positioned such that said first detector device and said radiation source are disposed with the selected location therebetween, said second detector device being disposed between said radiation source and the selected location. 8. The system of claim 4 wherein the scanning point selection means comprises: 9. The system of claim 7, further comprising filtering means for determining the identity of at least a grouping of atomic elements disposed between the radiation source and selected location second detection device. 10. The system of claim 8, wherein said first and second rotating disks are comprised of a material having a high atomic number, and wherein said spirally-shaped apertures of said first and second rotating disks are shaped in the form of spiral parabolic curves respectively represented by the equations in polar coordinates: ##EQU3## where a represents a constant, .theta. represents the polar angle in radian measure from the horizontal axis, and R.sub.1 and R.sub.2 represent the radius vector of disks, the first and second, rotating respectively. 11. The system of claim 3, wherein said first and second rotating disks are comprised of a material having a high atomic number, and wherein said spirally-shaped apertures of said first and second rotating disks are shaped in the form of spiral Archimedian curves respectively represented by the equations in polar coordinates: EQU R.sub.1 =a.times..theta., and EQU R.sub.2 =a.times.(.pi.-.theta.), 12. The system of claim 8 wherein said first and second rotating disk are comprised of a material having a high atomic number, and wherein said spirally-shaped apertures of said first and second rotating disks are shaped in the form of spiral Archimedian curves respectively represented by the equations in polar coordinates: EQU R.sub.1 =a.times..theta., and EQU R.sub.2 =a.times.(.pi.-.theta.), 13. The system of claim 3, wherein said first and second rotating disks are comprised of a material having a high atomic number, and wherein said spirally-shaped apertures of said first and second rotating disks are shaped in the form of spiral quadradic curves respectively represented by the equations in polar coordinates: EQU R.sub.1 =a.times..theta..sup.2, and EQU R.sub.2 =a.times.(.pi.-.theta.).sup.2, 14. The system of claim 8 wherein said first and second rotating disks are comprised of a material having a high atomic number, and wherein said spirally-shaped apertures of said first and second rotating disks are shaped in the form of spiral quadradic curves respectively represented by the equations in polar coordinates: EQU R.sub.1 =a.times..theta..sup.2, and EQU R.sub.2 =a.times.(.pi.-.theta.).sup.2, 15. The system of claim 3, wherein the system further comprises an image memory, responsive to said data processing means, for storing the signals processed by said data processing means, said display means being responsive to the signals stored by said image memory to generate the radiographic image of the predetermined area of the object. 16. The system of claim 8 wherein the system further comprises an image memory, responsive to said data processing means, for storing the signals processed by said data processing means, said display means being responsive to the signals stored by said image memory to generate the radiographic image of the predetermined area of the object. 17. A method for radiographically inspecting a predetermined area of relatively stationary object positioned at a selected location comprising the steps of: 18. The method of claim 17 wherein the step of sequentially selecting and transmitting the portions from the cross-sectional area of the first radiation beam comprises the substeps of: 19. The method of claim 17 wherein the method further comprises the step of storing the processed signals for generating a radiographic image of the predetermined area of the object. 20. A system for radiographically inspecting a predetermined area of a relatively stationary object positioned at a selected location, comprising: 21. The system of claim 20 further comprising filtering means disposed in the radiation path between the radiation source and the detection means for determining the identity of at least a grouping of atomic elements, and wherein the filtering means includes a member composed of a selected atomic element having an area corresponding to at least the radiation beam area; and 22. A system for radiographically inspecting a predetermined area of a relatively stationary object positioned at a selected location, comprising: 23. The system of claim 22, further comprising filtering means disposed in the radiation path between the radiation source and the detection means for determining the identity of at least a grouping of atomic elements; and wherein the filtering means includes a member composed of a selected atomic element having an area corresponding to at least the radiation beam area. 24. The system of claim 22 further comprising filtering means disposed in the radiation path between the radiation source and the detection means for determining the identity of at least a grouping of atomic elements. 25. The system of claim 24 wherein the filtering means comprises a member composed of a selected atomic element having an area corresponding to at least the radiation beam area; and 26. The system of claim 22 wherein said first and second disks are comprised of a material having a high atomic number, and wherein said apertures of said first and second disks are shaped in the form of spiral parabolic curves respectively represented by the equations in polar coordinates: EQU R.sub.1 =a.times.0, and EQU R.sub.2 =a.times.(.pi.-0), 27. The system of claim 22 wherein said first and second disk are comprised of a material having a high atomic number, and wherein said aperture of said first and second rotating disks are shaped in the form of spiral Archimedian curves respectively represented by the equations in polar coordinates: EQU R.sub.1 =a.times.0, and EQU R.sub.2 =a.times.(.pi.-0), 28. The system of claim 24 wherein said first and second disks are comprised of a material having a high atomic number, and wherein said apertures of said first and second rotating disks are shaped in the form of spiral Archimedian curves respectively represented by the equations in polar coordinates: EQU R.sub.1 =a.times.0, and EQU R.sub.2 =a.times.(.pi.-0), 29. The system of claim 22 wherein said first and second rotating disks are comprised of a material having a high atomic number, and wherein said spirally-shaped apertures of said first and second rotating disks are shaped in the form of spiral quadradic curves respectively represented by the equation in polar coordinates: EQU R.sub.1 =a.times.0.sup.2, and EQU R.sub.2 =a.times.(.pi.-0).sup.2, 30. The system of claim 24 wherein said first and second rotating disks are comprised of a material having a high atomic number, and wherein said spirally-shaped apertures of said first and second rotating disks are shaped in the form of spiral quadradic curves respectively represented by the equations in polar coordinates: EQU R.sub.1 =a.times.0.sup.2, and EQU R.sub.2 =a.times.(.pi.-0).sup.2, 31. The system of claim 22, wherein the system further comprises an image memory, responsive to said data processing means, for storing the signals processed by said data processing means, said display means being responsive to the signals stored by said image memory to generate the radiographic image of the predetermined area of the object. 32. The system of claim 24 wherein the system further comprises an image memory, responsive to said data processing means, for storing the signals processed by said data processing means, said display means being responsive to the signals stored by said image memory to generate the radiographic image of the predetermined area of the object. 33. The system of claim 22, wherein said radiation source includes means operative to transmit radiation of a selected energy intensity, and wherein said first disk is rotatable a distance corresponding to a width of the aperture at the end of a predetermined time period, and said second disk is rotatable completely during a predetermined time period, said time period being preselected in accordance with the selected energy intensity. 34. The system of claim 33 wherein the energy intensity is selected in accordance with the selected element. 35. A method for radiographically inspecting a predetermined area of a relatively stationary object, disposed at a selected location along a radiation path, comprising the steps of: