Fission Fragment/fissionable Isotope Detection System Patents (Class 250/370.03)
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Patent number: 10241061Abstract: A non-destructive inspection device 10 using backscattering of neutrons includes a neutron source 3 that radiates a pulse neutron beam to a surface 1a of an inspection target 1, a neutron detection device 5 that detects scattered neutrons scattered in the inspection target 1 and returned, and a measurement device 7 that measures the detection number of scattered and returned neutrons detected by the neutron detection device 5 and generates detection number data expressing the detection number with respect to time.Type: GrantFiled: March 2, 2018Date of Patent: March 26, 2019Assignee: RIKENInventors: Yoshie Otake, Yoshimasa Ikeda
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Patent number: 8538728Abstract: According to one embodiment, a method for identifying radio-nuclides includes receiving spectral data, extracting a feature set from the spectral data comparable to a plurality of templates in a template library, and using a branch and bound method to determine a probable template match based on the feature set and templates in the template library. In another embodiment, a device for identifying unknown radio-nuclides includes a processor, a multi-channel analyzer, and a memory operatively coupled to the processor, the memory having computer readable code stored thereon. The computer readable code is configured, when executed by the processor, to receive spectral data, to extract a feature set from the spectral data comparable to a plurality of templates in a template library, and to use a branch and bound method to determine a probable template match based on the feature set and templates in the template library.Type: GrantFiled: April 29, 2010Date of Patent: September 17, 2013Assignee: Lawrence Livermore National Security, LLCInventor: Karl Einar Nelson
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Patent number: 8417467Abstract: According to one embodiment, a method for estimating an activity of one or more radio-nuclides includes receiving one or more templates, the one or more templates corresponding to one or more radio-nuclides which contribute to a probable solution, receiving one or more weighting factors, each weighting factor representing a contribution of one radio-nuclide to the probable solution, computing an effective areal density for each of the one more radio-nuclides, computing an effective atomic number (Z) for each of the one more radio-nuclides, computing an effective metric for each of the one or more radio-nuclides, and computing an estimated activity for each of the one or more radio-nuclides. In other embodiments, computer program products, systems, and other methods are presented for estimating an activity of one or more radio-nuclides.Type: GrantFiled: April 29, 2010Date of Patent: April 9, 2013Assignee: Lawrence Livermore National Security, LLCInventor: Karl Einar Nelson
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Patent number: 8110807Abstract: The invention uses a series of combined passive neutron and gamma ray sensors systematically placed along a path of commercial traffic, for example an airport runway, combined with a pulsed source of low energy protons and deuterons. The pulsed source produces monoenergetic gamma rays and low energy (60 keV) neutrons. This pulsed source uses a pinch-reflex ion diode operated on a pulsed power generator to produce proton beams. These beams bombard a PTFE (Teflon) target to produce characteristic gamma-rays. These gamma rays would induce a fission reaction in any fissile material creating gamma rays and neutrons. The passive sensors located in the path of commercial traffic would sense both the resultant gamma and neutron products of the reaction.Type: GrantFiled: March 6, 2009Date of Patent: February 7, 2012Assignee: The United States of America as represented by the Defense Threat Reduction AgencyInventor: Richard Gullickson
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Patent number: 7973287Abstract: A system and method for detection of alpha particles generated by a test material in proximity to a light atomic weight element. The system includes a neutron detector that is configured to detect a rate of generation of neutrons produced by an (alpha, n) reaction between the test material and the light atomic weight element. There is also at least one gamma-ray detector configured to measure a rate of generation of 511 keV gamma rays produced by an annihilation reaction triggered by a positron emission from a daughter product of the light atomic weight element. A comparator is configured to compare the rate of generation of neutrons and the rate of generation of 511 keV gamma rays.Type: GrantFiled: August 14, 2007Date of Patent: July 5, 2011Assignee: Nucsafe, IncInventors: Richard A. Craig, Richard S. Seymour
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Publication number: 20110079728Abstract: A radiation detector is disclosed. The detector has an entrance opening etched through a low-resistivity volume of silicon, a sensitive volume of high-resistivity silicon for converting the radiation particles into detectable charges, and a passivation layer between the low and high-resistivity silicon layers. The detector also has electrodes built in the form of vertical channels for collecting the charges generated in the sensitive volume, and read-out electronics for generating signals based on the collected charges.Type: ApplicationFiled: June 4, 2010Publication date: April 7, 2011Applicants: FinPhys Oy, Consejo Superior de Investigaciones Cientificas (CSIC)Inventors: Francisco Garcia, Risto Orava, Manuel Lozano, Giulio Pellegrini
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Publication number: 20100224786Abstract: The invention uses a series of combined passive neutron and gamma ray sensors systematically placed along a path of commercial traffic, for example an airport runway, combined with a pulsed source of low energy protons and deuterons. The pulsed source produces monoenergetic gamma rays and low energy (60 keV) neutrons. This pulsed source uses a pinch-reflex ion diode operated on a pulsed power generator to produce proton beams. These beams bombard a PTFE (Teflon) target to produce characteristic gamma-rays. These gamma rays would induce a fission reaction in any fissile material creating gamma rays and neutrons. The passive sensors located in the path of commercial traffic would sense both the resultant gamma and neutron products of the reaction.Type: ApplicationFiled: March 6, 2009Publication date: September 9, 2010Applicant: United States of America, as represented by the Defense Threat Reduction AgencyInventor: Richard Gullickson
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Publication number: 20100019160Abstract: A neutron detector composed of a matrix of scintillating particles imbedded in a lithiated glass is disclosed. The neutron detector detects the neutrons by absorbing the neutron in the 6Li isotope which has been enriched from the natural isotopic ratio to a commercial ninety five percent. The utility of the detector is optimized by suitably selecting scintillating particle sizes in the range of the alpha and the triton. Nominal particle sizes are in the range of five to twenty five microns depending upon the specific scintillating particle selected.Type: ApplicationFiled: August 31, 2009Publication date: January 28, 2010Applicant: Neutron Sciences, Inc.Inventor: Steven Wallace
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Patent number: 7633062Abstract: A portal monitoring system has a cosmic ray charged particle tracker with a plurality of drift cells. The drift cells, which can be for example aluminum drift tubes, can be arranged at least above and below a volume to be scanned to thereby track incoming and outgoing charged particles, such as cosmic ray muons, whilst also detecting gamma rays. The system can selectively detect devices or materials, such as iron, lead, gold and/or tungsten, occupying the volume from multiple scattering of the charged particles passing through the volume and can also detect any radioactive sources occupying the volume from gamma rays emitted therefrom. If necessary, the drift tubes can be sealed to eliminate the need for a gas handling system. The system can be employed to inspect occupied vehicles at border crossings for nuclear threat objects.Type: GrantFiled: June 29, 2007Date of Patent: December 15, 2009Assignee: Los Alamos National Security, LLCInventors: Christopher Morris, Konstantin N. Borozdin, J. Andrew Green, Gary E. Hogan, Mark F. Makela, William C. Priedhorsky, Alexander Saunders, Larry J. Schultz, Michael J. Sossong
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Patent number: 7349517Abstract: The burnout of a fuel element in a reactor is determined by first transferring a fuel element from a reactor to a measuring position and then subjecting the transferred fuel element at the position to a neutron flux. A first detector measures the total ? radiation emitted by the transferred fuel element and thereafter, if the radiation measured by the first detector exceeds a predetermined first limit, the transferred fuel element is returned back to the reactor. If not, a second detector measures a magnitude of high energy ? radiation above 1 MeV emitted by the transferred fuel element and thereafter only if the radiation measured by the second detector exceeds a predetermined second limit, the transferred fuel element is transferred back to the reactor. The element is not returned to the reactor if the radiation measured by the second detector is below the second limit.Type: GrantFiled: January 15, 2004Date of Patent: March 25, 2008Assignee: Forschungszentrum Julich GmbHInventor: Peter Pohl
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Patent number: 7064337Abstract: A portable gamma ray detection apparatus having a gamma ray detector encapsulated by a compact isolation structure having at least two volumetrically-nested enclosures where at least one is a thermal shield. The enclosures are suspension-mounted to each other to successively encapsulate the detector without structural penetrations through the thermal shields. A low power cooler is also provided capable of cooling the detector to cryogenic temperatures without consuming cryogens, due to the heat load reduction by the isolation structure and the reduction in the power requirements of the cooler. The apparatus also includes a lightweight portable power source for supplying power to the apparatus, including to the cooler and the processing means, and reducing the weight of the apparatus to enable handheld operation or toting on a user's person.Type: GrantFiled: April 8, 2003Date of Patent: June 20, 2006Assignee: The Regents of the University of CaliforniaInventors: Mark S. Rowland, Douglas E. Howard, James L. Wong, James L. Jessup, Greg M. Bianchini, Wayne O. Miller
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Publication number: 20040114716Abstract: A remote sensing device for detecting materials of varying atomic numbers and systems and methods relating thereto. A system for identifying a material includes a photon beam flux monitor for resolving a high-energy beam. A method for identifying a material includes casting an incident photon beam on the material and detecting an emerging photon beam with an array of fission-fragment detectors, a first set of scintillator paddles, and a second set of scintillator paddles.Type: ApplicationFiled: October 27, 2003Publication date: June 17, 2004Inventor: Philip L. Cole
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Patent number: 6596998Abstract: A method for determining which of a plurality of detectors transmitted a signal, such as a signal related to neutron or gamma emissions, includes connecting each of the detectors to a single cable, such as an environmentally rugged cable. Signals are transmitted from each of the detectors over the single cable. The two ends of the cable are connected to two receivers. A different unique delay is introduced between receipt by the two receivers of a signal over the cable for each of the detectors. The receivers, which have a preamplifier, an amplifier and a discriminator, receive the signals from the two ends of the cable. A timing analyzer, such as a time-to-amplitude converter, measures a delay between one signal from one end and the other signal from the other end of the cable. A processor employs the amplitude of the signal output by the timing analyzer.Type: GrantFiled: July 31, 2000Date of Patent: July 22, 2003Assignee: Westinghouse Electric Company LLCInventor: George G. Siedel
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Patent number: 6479825Abstract: A low-energy particle sensor includes current collection areas which take the form of diodes partially covering the substrate. In detection areas defined alongside the collection areas the small thickness of the material enables low-energy particles (in particular a particles or protons) to penetrate the substrate. The currents generated by particles forming electron-hole pairs in this substrate are collected by the diode regions and sent to a load circuit. Applications include sensors for detectors of products resulting from collisions brought about in particle physics research apparatus.Type: GrantFiled: July 14, 2000Date of Patent: November 12, 2002Assignee: CSEM Centre Suisse d'Electronique et de Microtechnique SAInventor: Paul Weiss
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Patent number: 6255657Abstract: In one aspect, the invention encompasses a method of detecting radioactive decay, comprising: a) providing a sample comprising a radioactive material, the radioactive material generating decay particles; b)providing a plurality of detectors proximate the sample, the detectors comprising a first set and a second set, the first set of the detectors comprising liquid state detectors utilizing liquid scintillation material coupled with photo tubes to generate a first electrical signal in response to decay particles stimulating the liquid scintillation material, the second set of the detectors comprising solid state detectors utilizing a crystalline solid to generate a second electrical signal in response to decay particles stimulating the crystalline solid; c) stimulating at least one of the detectors to generate at least one of the first and second electrical signals, the at least one of the first and second electrical signals being indicative of radioactive decay in the sample.Type: GrantFiled: September 1, 1998Date of Patent: July 3, 2001Assignee: Bechtel BWXT Idaho, LLCInventors: Jerald D. Cole, Mark W. Drigert, Edward L. Reber, Rahmat Aryaeinejad