Patent Number: 
Section: claims

1. A product irradiator comprising:a radiation source for producing a radiation beam directed towards a product requiring irradiation,an adjustable collimator positioned between said radiation source and said product, said adjustable collimator having an aperture for shaping said beam,a rotatable turntable for receiving said product, anda control system in operative communication with said adjustable collimator and said turntable configured to adjust the size of said aperture to modulate a width of the beam as a function of an angular orientation of said turntable to produce a substantially uniform dose of radiation throughout the product during irradiation. 2. The product irradiator of claim 1, wherein said radiation source is selected from a group consisting of gamma, X-ray, and electron beam. 3. The product irradiator of claim 2, wherein said radiation source is an X-ray radiation source comprising an electron accelerator for producing high energy electrons, a scanning horn for directing the high energy electrons, and a converter for converting the high energy electrons into X-rays. 4. The product irradiator of claim 3, wherein the converter further comprises a cooling system for dissipating heat produced from conversion of high energy electrons into X-rays in said converter. 5. The product irradiator of claim 1, further comprising a detection system. 6. The product irradiator of claim 5, further comprising an auxiliary shield. 7. The product irradiator of claim 5, wherein said detection system measures at least one of the following parameters: transmitted radiation, instantaneous angular velocity of said turntable, angular orientation of said turntable, power of a radiation beam produced by said radiation source, energy of said radiation beam, width of said radiation beam, vertical scan speed, collimator aperture, position of an auxiliary shield, offset of a radiation beam axis from an axis of rotation of said turntable, distance of said turntable from said collimator, and distance of said collimator from said radiation source. 8. The product irradiator of claim 7, wherein said detection system is operatively linked with said control system. 9. A method using radiation processing comprising:i) placing a product onto a turntable, rotating said turntable, and establishing at least one of the following properties: length, width, height, density, and density distribution of said product;ii) modulating a width of a beam as a function of an angular orientation of said turntable by adjusting the size of a collimator aperture;iii) producing a collimated radiation beam; andiv) rotating said product within said collimated radiation beam for a period of time sufficient to produce a substantially uniform dose of radiation throughout the product. 10. The method of claim 9, wherein, in said step of adjusting, an angular velocity of said turntable is a parameter that is adjusted. 11. The method of claim 10, wherein, in said step of adjusting, said collimated radiation beam is a collimated X-ray beam produced from high energy electrons generated by an electron accelerator, and power of said high energy electrons is adjusted. 12. The method of claim 11, wherein during or following said step of rotating, is:detecting X-rays transmitted through said product. 13. The method of claim 12, wherein, during or following said step of detecting, is:processing information obtained in said detecting step by a control system and altering of any of the following parameters: collimator aperture, distance between said turntable and collimator, turntable offset, position of an auxiliary shield, angular velocity of said turntable, and power of said high energy electrons. 14. The method of claim 9, wherein the step of adjusting further comprises adjusting at least one of the following parameters: collimator aperture, distance between said turntable and collimator, turntable offset, and position of an auxiliary shield. 15. A product irradiator comprising:i) an X-ray radiation source essentially consisting of an electron accelerator for producing high energy electrons, a scanning horn for directing said high energy electrons towards a convertor, said converter for converting said high energy electrons into X-rays to produce an X-ray beam, said X-ray beam directed towards a product requiring irradiation;ii) an adjustable collimator having an aperture for shaping said X-ray beam;iii) a rotatable turntable upon which said product is placed, andiv) a control system in operative communication with said electron accelerator, said adjustable collimator, and said turntable, configured to adjust the size of said aperture of said collimator to modulate a width of the beam as a function of an angular orientation of said turntable, to produce a substantially uniform dose of radiation throughout the product. 16. The product irradiator of claim 15, farther comprising a detection system in operative association with said control system. 17. The product irradiator of claim 16, wherein said turntable is movable towards or away from said adjustable collimator, or said turntable is movable laterally, so that an axis of rotation of said product on said turntable is offset from an axis of said X-ray beam. 18. The product irradiator of claim 17, further comprising an auxiliary shield. 19. The product irradiator of claim 18, wherein said detection system measures at least one of the following parameters: transmitted X-ray irradiation, instantaneous angular velocity of said turntable, angular orientation of said turntable, power of said high energy electrons, width of a high energy electron beam, energy of said X-ray beam, aperture of said adjustable collimator, position of said auxiliary shield, offset of said radiation beam from an axis of rotation of said turntable, distance of said turntable from said collimator, and distance of said collimator from said radiation source. 20. A method for irradiating a product on a turntable, comprising:i) rotating the product on the turntable, said product selected from the group consisting of foodstuffs, powdered goods, medical articles, laboratory supplies, medical waste, and waste;ii) irradiating the product with a radiation beam during rotation; andiii) modulating a width of the radiation beam as a function of an angular orientation of said turntable by adjusting the size of a collimator aperture to produce a substantially uniform dose of radiation throughout the product. 21. The method of claim 20, further including modulating a rate of rotation of the turntable during irradiation. 22. The method of claim 20, further including modulating an intensity of the radiation beam during rotation. 23. The method of claim 20, further including modulating a rate of rotation of the turntable and the intensity of the radiation beam during rotation. 24. The method of claim 20, further including receiving a signal from a radiation detection system and modulating at least one of: the width of the radiation beam, a rate of rotation of the turntable, and an intensity of the radiation beam, based upon the received signal. 25. The method of claim 20, wherein the radiation beam is an X-ray beam. 26. The method of claim 20, wherein the radiation beam is an X-ray beam produced using bremsstrahlung. 27. The method of claim 20, wherein vertical scan speed of said radiation beam is modulated during product irradiation. 28. A method of radiating a product on a turntable including:i) rotating the product on the turntable, said product selected from the group consisting of foodstuffs, powdered goods, medical articles, laboratory supplies, medical waste, and waste;ii) irradiating the product with a radiation beam during rotation;iii) modulating a rate of rotation of the turntable during rotation; andiv) modulating a width of the radiation beam as a function of an angular orientation of said turntable by adjusting the size of a collimator aperture to produce a substantially unicorn dose of radiation throughout the product. 29. The method of claim 28, further including modulating an intensity of the radiation beam during rotation. 30. The method of claim 28, further including receiving a signal from a radiation detection system and modulating the rate of rotation of the turntable during rotation based upon the signal received from the detection system. 31. The method of claim 28, further including receiving a signal from a radiation detection system and modulating at least one of: the width of the radiation beam, the rate of rotation of the turntable, and an intensity of the radiation beam, based upon the signal received from the detection system. 32. The method of claim 28, wherein the radiation beam is an X-ray beam. 33. The method of claim 28, wherein the radiation beam is an X-ray beam produced using bremsstrahlung. 34. The method of claim 28, wherein the irradiation produces a Dose Uniformity Ratio of between about 1 to about less than 2 in the product. 35. The method of claim 28, wherein vertical scan speed of said radiation beam is modulated during product irradiation. 36. A method for irradiating a product on a turntable comprising:i) rotating the product on the turntable, said product selected from the group consisting of foodstuffs, powdered goods, medical articles, laboratory supplies, medical waste, and waste;ii) irradiating the product with a radiation beam during rotation;iii) modulating an intensity of the radiation beam during rotation; andiv) modulating a width of the radiation beam as a function of an angular orientation of said turntable by adjusting the size of a collimator aperture, to produce a substantially uniform dose of radiation throughout the product. 37. The method of claim 36, further including modulating a rate of rotation of the turntable during rotation. 38. The method of claim 36, further including receiving a signal from a radiation detection system and modulating the intensity of the radiation beam during rotation based upon the signal received from the detection system. 39. The method of claim 36, further including receiving a signal from a radiation detection system and modulating at least one of: the width of the radiation beam, a rate of rotation of the turntable, and the intensity of the radiation beam, based upon the signal received from the detection system. 40. The method of claim 36, wherein the radiation beam is an X-ray beam. 41. The method of claim 36, wherein the radiation beam is an X-ray beam produced using bremsstrahlung. 42. A method for irradiating a product on a turntable comprising:i) performing a diagnostic scan of the product, said product selected from the group consisting of foodstuffs, powdered goods, medical articles, laboratory supplies, medical waste, and waste;ii) rotating the product on the turntable;iii) irradiating the product with a radiation beam during rotation; andiv) modulating a width of the radiation beam as a function of an angular orientation of said turntable by adjusting the size of a collimator aperture, based upon the diagnostic scan, to produce a substantially uniform dose of radiation throughout the product. 43. The method of claim 42, further including modulating a rate of rotation of the product based upon the diagnostic scan. 44. The method of claim 42, further including modulating an intensity of the radiation beam during rotation of the product based upon the diagnostic scan. 45. The method of claim 42, further including modulating a rate of rotation of the product and an intensity of the radiation beam during rotation based upon the diagnostic scan. 46. The method of claim 42, further including generating a signal from a radiation detection system and modulating at least one of: the width of the radiation beam, a rate of rotation of the product, and an intensity of the radiation beam, based upon the signal. 47. The method of claim 42, wherein vertical scan speed of said radiation beam is modulated during product irradiation. 48. A method for irradiating a product on a turntable comprising:i) performing a diagnostic scan of the product, said product selected from the group consisting of foodstuffs, powdered goods, medical articles, laboratory supplies, medical waste, and waste;ii) rotating the product on the turntable;iii) irradiating the product with a radiation beam during rotation;iv) modulating a rate of rotation of the turntable during rotation, based upon the diagnostic scan; andv) modulating a width of the radiation beam as a function of an angular orientation of said turntable by adjusting the size of a collimator aperture, based upon the diagnostic scan, to produce a substantially uniform dose of radiation throughout the product. 49. The method of claim 48, further including modulating an intensity of the radiation beam during rotation of the product based upon the diagnostic scan. 50. The method of claim 48, further including generating a signal from a radiation detection system and modulating at least one of: the width of the radiation beam, the rate of rotation of the turntable, and an intensity of the radiation beam, based upon the signal. 51. The method of claim 48, wherein vertical scan speed of said radiation beam is modulated during product irradiation. 52. A method for irradiating a product on a turntable to produce a low Dose Uniformity Ratio within the product comprising:i) performing a diagnostic scan of the product, said product selected from the group consisting of foodstuffs, powdered goods, medical articles, laboratory supplies, medical waste, and waste;ii) rotating the product on the turntable;iii) irradiating the product with a radiation beam during rotation;iv) modulating an intensity of the radiation beam during rotation based upon the diagnostic scan; andv) modulating a width of the radiation beam as a function of an angular orientation of said turntable by adjusting the size of a collimator aperture, based upon the diagnostic scan, to produce a substantially uniform dose of radiation throughout the product. 53. The method of claim 52, further including modulating a rate of rotation of the product based upon the diagnostic scan. 54. The method of claim 52, further including generating a signal from a radiation detection system and modulating at least one of: the width of the radiation beam, a rate of rotation of the turntable, and the intensity of the radiation beam, based upon the received signal. 55. An apparatus for irradiating a product, comprising,a radiation detection system that measures an amount of radiation absorbed by at least part of the product,a radiation source for producing a beam, said beam directed towards said product,an adjustable collimator having an aperture for shaping said beam, said adjustable collimator positioned between said radiation source and said product,a rotatable turntable for receiving said product, anda control system in operative communication with said adjustable collimator, and said turntable,wherein each of said radiation source, adjustable collimator and turntable have at least one parameter that is capable of being adjusted automatically based upon a measurement made by the detection system to achieve a low Dose Uniformity Ratio in a product during irradiation, andwherein the control system comprises instructions for adjusting the size of said aperture of said collimator to modulate a width of the beam as a function of an angular orientation of said turntable to produce a substantially uniform dose of radiation throughout the product. 56. The apparatus of claim 55, wherein the at least one adjustable parameter for the source is beam power. 57. The apparatus of claim 55, wherein the at least one adjustable parameter for the turntable is instantaneous turntable rotation rate. 58. The apparatus of claim 55, wherein the radiation source is an X-ray beam. 59. The apparatus of claim 55, wherein the radiation source is an X-ray beam produced using bremsstrahlung. 60. The apparatus of claim 55, wherein the radiation source comprises an electron accelerator that produces an electron beam, a scanning horn, and a converter to convert the electron beam into X-rays. 61. The apparatus of claim 60, wherein the converter is a Ta converter. 62. The apparatus of claim 55, wherein the radiation source is offset from an axis of rotation of the turntable. 63. The apparatus of claim 55, further comprising an auxiliary shield. 64. The apparatus of claim 63, wherein the auxiliary shield extends across the entire aperture of the collimator. 65. The apparatus of claim 63, wherein the auxiliary shield is of a width that is less than that of an aperture of the collimator. 66. The apparatus of claim 63, wherein the auxiliary shield is a Ta auxiliary shield. 67. The apparatus of claim 55, wherein the radiation detection system is adapted for operation during a diagnostic scan before the irradiation. 68. The apparatus of claim 55, wherein the radiation detection system is adapted for operation during a diagnostic scan during the irradiation. 69. A medium storing instructions adapted to be executed by a processor to modulate a the size of a collimator aperture to adjust a width of a radiation beam as a function of an angular orientation of a turntable, while a product is being rotated by said turntable, to produce a substantially uniform dose of radiation throughout the product, and irradiated by said radiation beam, and to modulate vertical scan speed, wherein the radiation beam is collimated by the collimator. 70. The medium of claim 69, wherein the instructions are further adapted to be executed by a processor to modulate a rate at which the product is rotated during irradiation. 71. The medium of claim 69, wherein the instructions are further adapted to be executed by a processor to modulate an intensity of the radiation beam during irradiation. 72. The medium of claim 69, wherein the instructions are further adapted to be executed by a processor to modulate a rate at which the product is rotated and an intensity of the radiation beam during irradiation. 73. The medium of claim 69, wherein the instructions are further adapted to be executed by a processor to produce a low Dose Uniformity Ratio in the product. 74. A medium storing instructions adapted to be executed by a processor to modulate a rate of rotation of a turntable and to modulate the size of a collimator aperture, to produce a substantially uniform dose of radiation throughout a product with a Dose Uniformity Ratio (DUR) of between about 1 to less than about 2, while the product is being irradiated by a radiation beam, wherein the size of said collimator aperture is adjusted to modulate a width of the radiation beam as a function of an angular orientation of said turntable. 75. The medium of claim 74, wherein the instructions are further adapted to be executed by a processor to modulate an intensity of the radiation beam during irradiation. 76. A medium storing instructions adapted to be executed by a processor to modulate an intensity of a radiation beam and the size of a collimator aperture, while a product is being rotated by a turntable, said turntable rotatable through 360°, and irradiated by the radiation beam, and to modulate vertical scan speed of the radiation beam, wherein the size of said collimator aperture is adjusted to modulate a width of the radiation beam as a function of an angular orientation of said turntable, to produce a substantially uniform dose of radiation throughout the product. 77. The medium of claim 76, wherein the instructions are further adapted to be executed by a processor to produce a low Dose Uniformity Ratio in the product. 78. A medium storing instructions adapted to be executed by a processor to receive data from a detection system and to modulate the size of a collimator aperture to adjust a width of a radiation beam as a function of an angular orientation of a turntable, based upon the received data, and to modulate a vertical scan speed, wherein the collimator collimates a radiation beam that irradiates a product, to produce a substantially uniform dose of radiation throughout the product. 79. The medium of claim 78, wherein the instructions are further adapted to be executed by the processor to modulate a rate at which the product is rotated, based upon data received from the detection system. 80. The medium of claim 78, wherein the instructions are further adapted to be executed by the processor to modulate an intensity of the radiation beam, based upon data received from the detection system. 81. The medium of claim 78, wherein the instructions are further adapted to be executed by the processor to modulate a rate of rotation of the product and an intensity of the radiation beam, based upon data received from the detection system. 82. The medium of claim 78, wherein data received from the detection system is generated during a diagnostic scan before the product is irradiated. 83. The medium of claim 78, wherein data received from the detection system is generated during a diagnostic scan while the product is irradiated. 84. A medium storing instructions adapted to be executed by a processor to receive data from a detection system that characterizes a product, to modulate a rate of rotation of a turntable, and to modulate the size of a collimator aperture to adjust a width of a radiation beam as a function of an angular orientation of said turntable, based upon the received data, to produce a substantially uniform dose of radiation throughout the product. 85. The medium of claim 84, wherein the instructions are further adapted to be executed by the processor to modulate vertical scan speed, based upon data received from the detection system. 86. The medium of claim 84, wherein the instructions are further adapted to be executed by the processor to modulate an intensity of a radiation beam, based upon data received from the detection system. 87. The medium of claim 84, wherein data received from the detection system is generated during a diagnostic scan before the product is irradiated. 88. The medium of claim 84, wherein data received from the detection system is generated during a diagnostic scan while the product is irradiated. 89. A medium storing instructions adapted to be executed by a processor to receive data from a detection system characterizing a product, to modulate an intensity of a radiation beam, to modulate the size of a collimator aperture to adjust a width of the radiation beam as a function of an angular orientation of a turntable, and to modulate vertical scan speed of the radiation beam, based upon the received data, to produce a substantially uniform dose of radiation throughout the product. 90. A system for irradiating a product comprising;i) means for producing a radiation beam;ii) means for measuring an amount of radiation absorbed by at least part of the product;iii) means for adjustably setting a width of the radiation beam that irradiates the product;iv) means for rotating the product; andv) control means in operative communication with said means for adjustably setting a width of the radiation beam and said means for rotating the product, said control means comprising instructions for modulating a rate of rotation of the product and modulating the width of the radiation beam as a function of an angular orientation of said means for rotating the product by adjusting a size of a collimator aperture during irradiation, based upon a measured amount of radiation absorbed by at least a part of the product, to produce a substantially uniform dose of radiation throughout the product during irradiation. 91. The system of claim 90, further comprising means for modulating an intensity of the radiation beam based upon the measured amount of radiation absorbed by at least part of the product.