Irradiation system for production of gaseous radioisotopes used as tracers in industrial process measurements

The use of radioisotopes as radiotracers is considered the most important in diagnosing operation and troubleshooting of industrial process plants in chemical and petrochemical companies. They are used in analytical procedures to obtain qualitative and quantitative data systems, in physical and phys...

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Veröffentlicht in:	Progress in nuclear energy (New series) 2018-08, Vol.107, p.10-16
Hauptverfasser:	Cardozo, N.X., Omi, N.M., Ambiel, J.J., Feher, A., Napolitano, C.M., Somessari, S.L., Calvo, W.A.P.
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Sprache:	eng
Schlagworte:	Alanine Aluminum Argon-41 Chemical elements Connectors Cylinders Data systems Dosimeters Flow measurement Gaseous radioisotope production Industrial applications Industrial plants Industrial process measurement Irradiation Irradiation system Krypton Liquefied natural gas Neutron flux Nuclear physics Nuclear reactors Nuclear research Nuclear research and test reactors Organic chemistry Pressurization Qualitative analysis Radiation Radiation shielding Radioisotopes Stability tests Thermal neutrons Tomography Tracers
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creator	Cardozo, N.X. Omi, N.M. Ambiel, J.J. Feher, A. Napolitano, C.M. Somessari, S.L. Calvo, W.A.P.
description	The use of radioisotopes as radiotracers is considered the most important in diagnosing operation and troubleshooting of industrial process plants in chemical and petrochemical companies. They are used in analytical procedures to obtain qualitative and quantitative data systems, in physical and physicochemical studies transfers. In the production of gaseous radioisotopes used as tracers in industrial process measurements, argon-41 (41Ar) and krypton-79 (79Kr) stand out because each has low reactivity with other chemical elements. 41Ar is a transmitter range with high-energy (1.29 MeV) and a high percentage of this energy transformation (99.1%), resulting in relatively small quantities required in relation to the other, for an efficient detection, even in large thicknesses components. Nowadays, the production of gaseous radioisotopes in nuclear research reactors is performed in small quantities (batches), through quartz ampoules containing natural gas 40Ar or 78Kr. In this sense, the aim of this study is to develop an irradiation system for gaseous radioisotope production in continuous scale, applied in industrial applications of emission tomography and flow measurement. The irradiation system may produce 41Ar with activity of 7.4 × 1011 Bq (20 Ci) per irradiation cycle, through the Reactor IEA-R1 with 4.5 MW and average thermal neutron flux of 4.71 × 1013 ncm−2s−1 to meet an existing demand in NDT and inspections companies, and even needed by the Radiation Technology Centre, at IPEN/CNEN-SP. The irradiation system consists of an aluminium irradiation capsule, transfer lines, needle valves, ringed connections, quick connectors, manometer, vacuum system, dewar, lead shielding, storage and transport cylinders, among other components. The irradiation system was approved in the leakage and stability tests (bubble test, pressurization, evacuation and with leak detector equipment SPECTRON 600 T). In the experimental production obtaining 1.07 × 1011 Bq (2.9 Ci) of 41Ar, alanine dosimeters were distributed into various components of the irradiation system. In addition, exposure rates were determined in the lead shielding wall, in which the liquefied radioactive gas was concentrated, and in the storage and transport cylinders after 41Ar was transferred by the portable radiation meter Teletector® Probe 6150 AD-t/H.
doi_str_mv	10.1016/j.pnucene.2018.04.010
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In this sense, the aim of this study is to develop an irradiation system for gaseous radioisotope production in continuous scale, applied in industrial applications of emission tomography and flow measurement. The irradiation system may produce 41Ar with activity of 7.4 × 1011 Bq (20 Ci) per irradiation cycle, through the Reactor IEA-R1 with 4.5 MW and average thermal neutron flux of 4.71 × 1013 ncm−2s−1 to meet an existing demand in NDT and inspections companies, and even needed by the Radiation Technology Centre, at IPEN/CNEN-SP. The irradiation system consists of an aluminium irradiation capsule, transfer lines, needle valves, ringed connections, quick connectors, manometer, vacuum system, dewar, lead shielding, storage and transport cylinders, among other components. The irradiation system was approved in the leakage and stability tests (bubble test, pressurization, evacuation and with leak detector equipment SPECTRON 600 T). In the experimental production obtaining 1.07 × 1011 Bq (2.9 Ci) of 41Ar, alanine dosimeters were distributed into various components of the irradiation system. In addition, exposure rates were determined in the lead shielding wall, in which the liquefied radioactive gas was concentrated, and in the storage and transport cylinders after 41Ar was transferred by the portable radiation meter Teletector® Probe 6150 AD-t/H.</description><identifier>ISSN: 0149-1970</identifier><identifier>EISSN: 1878-4224</identifier><identifier>DOI: 10.1016/j.pnucene.2018.04.010</identifier><language>eng</language><publisher>Oxford: Elsevier Ltd</publisher><subject>Alanine ; Aluminum ; Argon-41 ; Chemical elements ; Connectors ; Cylinders ; Data systems ; Dosimeters ; Flow measurement ; Gaseous radioisotope production ; Industrial applications ; Industrial plants ; Industrial process measurement ; Irradiation ; Irradiation system ; Krypton ; Liquefied natural gas ; Neutron flux ; Nuclear physics ; Nuclear reactors ; Nuclear research ; Nuclear research and test reactors ; Organic chemistry ; Pressurization ; Qualitative analysis ; Radiation ; Radiation shielding ; Radioisotopes ; Stability tests ; Thermal neutrons ; Tomography ; Tracers</subject><ispartof>Progress in nuclear energy (New series), 2018-08, Vol.107, p.10-16</ispartof><rights>2018 Elsevier Ltd</rights><rights>Copyright Elsevier BV Aug 2018</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c337t-82f83f0fae73319ee657536e7a2e31e07c682c59096e8de403e43150afc9ed723</citedby><cites>FETCH-LOGICAL-c337t-82f83f0fae73319ee657536e7a2e31e07c682c59096e8de403e43150afc9ed723</cites><orcidid>0000-0003-1691-2314</orcidid></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktohtml>$$Uhttps://dx.doi.org/10.1016/j.pnucene.2018.04.010$$EHTML$$P50$$Gelsevier$$H</linktohtml><link.rule.ids>314,780,784,3550,27924,27925,45995</link.rule.ids></links><search><creatorcontrib>Cardozo, N.X.</creatorcontrib><creatorcontrib>Omi, N.M.</creatorcontrib><creatorcontrib>Ambiel, J.J.</creatorcontrib><creatorcontrib>Feher, A.</creatorcontrib><creatorcontrib>Napolitano, C.M.</creatorcontrib><creatorcontrib>Somessari, S.L.</creatorcontrib><creatorcontrib>Calvo, W.A.P.</creatorcontrib><title>Irradiation system for production of gaseous radioisotopes used as tracers in industrial process measurements</title><title>Progress in nuclear energy (New series)</title><description>The use of radioisotopes as radiotracers is considered the most important in diagnosing operation and troubleshooting of industrial process plants in chemical and petrochemical companies. 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In this sense, the aim of this study is to develop an irradiation system for gaseous radioisotope production in continuous scale, applied in industrial applications of emission tomography and flow measurement. The irradiation system may produce 41Ar with activity of 7.4 × 1011 Bq (20 Ci) per irradiation cycle, through the Reactor IEA-R1 with 4.5 MW and average thermal neutron flux of 4.71 × 1013 ncm−2s−1 to meet an existing demand in NDT and inspections companies, and even needed by the Radiation Technology Centre, at IPEN/CNEN-SP. The irradiation system consists of an aluminium irradiation capsule, transfer lines, needle valves, ringed connections, quick connectors, manometer, vacuum system, dewar, lead shielding, storage and transport cylinders, among other components. The irradiation system was approved in the leakage and stability tests (bubble test, pressurization, evacuation and with leak detector equipment SPECTRON 600 T). In the experimental production obtaining 1.07 × 1011 Bq (2.9 Ci) of 41Ar, alanine dosimeters were distributed into various components of the irradiation system. 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They are used in analytical procedures to obtain qualitative and quantitative data systems, in physical and physicochemical studies transfers. In the production of gaseous radioisotopes used as tracers in industrial process measurements, argon-41 (41Ar) and krypton-79 (79Kr) stand out because each has low reactivity with other chemical elements. 41Ar is a transmitter range with high-energy (1.29 MeV) and a high percentage of this energy transformation (99.1%), resulting in relatively small quantities required in relation to the other, for an efficient detection, even in large thicknesses components. Nowadays, the production of gaseous radioisotopes in nuclear research reactors is performed in small quantities (batches), through quartz ampoules containing natural gas 40Ar or 78Kr. In this sense, the aim of this study is to develop an irradiation system for gaseous radioisotope production in continuous scale, applied in industrial applications of emission tomography and flow measurement. The irradiation system may produce 41Ar with activity of 7.4 × 1011 Bq (20 Ci) per irradiation cycle, through the Reactor IEA-R1 with 4.5 MW and average thermal neutron flux of 4.71 × 1013 ncm−2s−1 to meet an existing demand in NDT and inspections companies, and even needed by the Radiation Technology Centre, at IPEN/CNEN-SP. The irradiation system consists of an aluminium irradiation capsule, transfer lines, needle valves, ringed connections, quick connectors, manometer, vacuum system, dewar, lead shielding, storage and transport cylinders, among other components. The irradiation system was approved in the leakage and stability tests (bubble test, pressurization, evacuation and with leak detector equipment SPECTRON 600 T). In the experimental production obtaining 1.07 × 1011 Bq (2.9 Ci) of 41Ar, alanine dosimeters were distributed into various components of the irradiation system. In addition, exposure rates were determined in the lead shielding wall, in which the liquefied radioactive gas was concentrated, and in the storage and transport cylinders after 41Ar was transferred by the portable radiation meter Teletector® Probe 6150 AD-t/H.</abstract><cop>Oxford</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.pnucene.2018.04.010</doi><tpages>7</tpages><orcidid>https://orcid.org/0000-0003-1691-2314</orcidid></addata></record>
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subjects	Alanine Aluminum Argon-41 Chemical elements Connectors Cylinders Data systems Dosimeters Flow measurement Gaseous radioisotope production Industrial applications Industrial plants Industrial process measurement Irradiation Irradiation system Krypton Liquefied natural gas Neutron flux Nuclear physics Nuclear reactors Nuclear research Nuclear research and test reactors Organic chemistry Pressurization Qualitative analysis Radiation Radiation shielding Radioisotopes Stability tests Thermal neutrons Tomography Tracers
title	Irradiation system for production of gaseous radioisotopes used as tracers in industrial process measurements
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