Residual Stress Measurements in Extreme Environments for Hazardous, Layered Specimens

Background In nuclear fuel plates of low-enriched U-10Mo (LEU) clad with aluminum by hot isostatic pressing (HIP), post-irradiation stresses arising during reactor shutdown are a major concern for safe reactor operations. Measurement of those residual stresses has not previously been possible becaus...

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Veröffentlicht in:	Experimental mechanics 2022-10, Vol.62 (8), p.1381-1400
Hauptverfasser:	Benefiel, B. C., Larsen, E. D., Prime, M. B., Phillips, A. M., Davies, K. B., Castano, D., Cole, J. I.
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Sprache:	eng
Schlagworte:	Advances in Residual Stress Technology Aluminum Biomedical Engineering and Bioengineering Characterization and Evaluation of Materials Compressive properties Control Cooling rate Dynamical Systems Electric discharge machining End milling Engineering Extreme environments Foils Hazardous areas Heterogeneity hot cell Hot isostatic pressing incremental slitting Inverse method Irradiation Lasers low enriched uranium MATERIALS SCIENCE Measurement methods nuclear fuel Nuclear fuels Optical Devices Optics Photonics Plates Regularization Regularization methods Residual stress residual stress management Shutdowns Slitting Solid Mechanics Strain gauges Thickness measurement Uranium Uranium base alloys Vibration
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creator	Benefiel, B. C. Larsen, E. D. Prime, M. B. Phillips, A. M. Davies, K. B. Castano, D. Cole, J. I.
description	Background In nuclear fuel plates of low-enriched U-10Mo (LEU) clad with aluminum by hot isostatic pressing (HIP), post-irradiation stresses arising during reactor shutdown are a major concern for safe reactor operations. Measurement of those residual stresses has not previously been possible because the high radioactivity of the plates requires handling only by remote manipulation in a hot cell. Objective The incremental slitting method for measuring through-thickness stress profiles was modified, and a system for automated, remote operation was built and tested. Methods Experimental modifications consisted of replacing electric-discharge machining (EDM) with a small end mill and strain-gauge measurements with cantilever displacement measurements. The inverse method used to calculate stresses was the pulse-regularization method modified to allow discontinuities across material interfaces. The new system was validated by comparing with conventional slitting on a depleted U-10Mo (DU) fuel plate. Results The new system was applied to two measurements each on six as-fabricated (pre-irradiation) LEU miniature fuel plates. Variations between the measurements at two locations in the same plate were strongly correlated with measured geometrical heterogeneity in the plate—a tilt in the fuel foil. Compressive stresses in the U-10Mo were shown to increase from 20 to 250 MPa as the ratio of aluminum thickness to U-10Mo thickness increased causing increased constraint during cooling. Faster cooling rates during processing also increased stress magnitudes. Conclusions The measurements trends agreed with data in the literature from similar plates made with DU, which further validates the method. Because other methods are impractical in a hot cell, the modified slitting method is now poised for the first measurements of post-irradiation stresses.
doi_str_mv	10.1007/s11340-021-00816-4
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C. ; Larsen, E. D. ; Prime, M. B. ; Phillips, A. M. ; Davies, K. B. ; Castano, D. ; Cole, J. I.</creator><creatorcontrib>Benefiel, B. C. ; Larsen, E. D. ; Prime, M. B. ; Phillips, A. M. ; Davies, K. B. ; Castano, D. ; Cole, J. I. ; Idaho National Lab. (INL), Idaho Falls, ID (United States) ; Los Alamos National Lab. (LANL), Los Alamos, NM (United States)</creatorcontrib><description>Background In nuclear fuel plates of low-enriched U-10Mo (LEU) clad with aluminum by hot isostatic pressing (HIP), post-irradiation stresses arising during reactor shutdown are a major concern for safe reactor operations. Measurement of those residual stresses has not previously been possible because the high radioactivity of the plates requires handling only by remote manipulation in a hot cell. Objective The incremental slitting method for measuring through-thickness stress profiles was modified, and a system for automated, remote operation was built and tested. Methods Experimental modifications consisted of replacing electric-discharge machining (EDM) with a small end mill and strain-gauge measurements with cantilever displacement measurements. The inverse method used to calculate stresses was the pulse-regularization method modified to allow discontinuities across material interfaces. The new system was validated by comparing with conventional slitting on a depleted U-10Mo (DU) fuel plate. Results The new system was applied to two measurements each on six as-fabricated (pre-irradiation) LEU miniature fuel plates. Variations between the measurements at two locations in the same plate were strongly correlated with measured geometrical heterogeneity in the plate—a tilt in the fuel foil. Compressive stresses in the U-10Mo were shown to increase from 20 to 250 MPa as the ratio of aluminum thickness to U-10Mo thickness increased causing increased constraint during cooling. Faster cooling rates during processing also increased stress magnitudes. Conclusions The measurements trends agreed with data in the literature from similar plates made with DU, which further validates the method. Because other methods are impractical in a hot cell, the modified slitting method is now poised for the first measurements of post-irradiation stresses.</description><identifier>ISSN: 0014-4851</identifier><identifier>EISSN: 1741-2765</identifier><identifier>DOI: 10.1007/s11340-021-00816-4</identifier><language>eng</language><publisher>New York: Springer US</publisher><subject>Advances in Residual Stress Technology ; Aluminum ; Biomedical Engineering and Bioengineering ; Characterization and Evaluation of Materials ; Compressive properties ; Control ; Cooling rate ; Dynamical Systems ; Electric discharge machining ; End milling ; Engineering ; Extreme environments ; Foils ; Hazardous areas ; Heterogeneity ; hot cell ; Hot isostatic pressing ; incremental slitting ; Inverse method ; Irradiation ; Lasers ; low enriched uranium ; MATERIALS SCIENCE ; Measurement methods ; nuclear fuel ; Nuclear fuels ; Optical Devices ; Optics ; Photonics ; Plates ; Regularization ; Regularization methods ; Residual stress ; residual stress management ; Shutdowns ; Slitting ; Solid Mechanics ; Strain gauges ; Thickness measurement ; Uranium ; Uranium base alloys ; Vibration</subject><ispartof>Experimental mechanics, 2022-10, Vol.62 (8), p.1381-1400</ispartof><rights>The Author(s) 2022</rights><rights>The Author(s) 2022. 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Measurement of those residual stresses has not previously been possible because the high radioactivity of the plates requires handling only by remote manipulation in a hot cell. Objective The incremental slitting method for measuring through-thickness stress profiles was modified, and a system for automated, remote operation was built and tested. Methods Experimental modifications consisted of replacing electric-discharge machining (EDM) with a small end mill and strain-gauge measurements with cantilever displacement measurements. The inverse method used to calculate stresses was the pulse-regularization method modified to allow discontinuities across material interfaces. The new system was validated by comparing with conventional slitting on a depleted U-10Mo (DU) fuel plate. Results The new system was applied to two measurements each on six as-fabricated (pre-irradiation) LEU miniature fuel plates. Variations between the measurements at two locations in the same plate were strongly correlated with measured geometrical heterogeneity in the plate—a tilt in the fuel foil. Compressive stresses in the U-10Mo were shown to increase from 20 to 250 MPa as the ratio of aluminum thickness to U-10Mo thickness increased causing increased constraint during cooling. Faster cooling rates during processing also increased stress magnitudes. Conclusions The measurements trends agreed with data in the literature from similar plates made with DU, which further validates the method. Because other methods are impractical in a hot cell, the modified slitting method is now poised for the first measurements of post-irradiation stresses.</description><subject>Advances in Residual Stress Technology</subject><subject>Aluminum</subject><subject>Biomedical Engineering and Bioengineering</subject><subject>Characterization and Evaluation of Materials</subject><subject>Compressive properties</subject><subject>Control</subject><subject>Cooling rate</subject><subject>Dynamical Systems</subject><subject>Electric discharge machining</subject><subject>End milling</subject><subject>Engineering</subject><subject>Extreme environments</subject><subject>Foils</subject><subject>Hazardous areas</subject><subject>Heterogeneity</subject><subject>hot cell</subject><subject>Hot isostatic pressing</subject><subject>incremental slitting</subject><subject>Inverse method</subject><subject>Irradiation</subject><subject>Lasers</subject><subject>low enriched uranium</subject><subject>MATERIALS SCIENCE</subject><subject>Measurement methods</subject><subject>nuclear fuel</subject><subject>Nuclear fuels</subject><subject>Optical Devices</subject><subject>Optics</subject><subject>Photonics</subject><subject>Plates</subject><subject>Regularization</subject><subject>Regularization methods</subject><subject>Residual stress</subject><subject>residual stress management</subject><subject>Shutdowns</subject><subject>Slitting</subject><subject>Solid Mechanics</subject><subject>Strain gauges</subject><subject>Thickness measurement</subject><subject>Uranium</subject><subject>Uranium base alloys</subject><subject>Vibration</subject><issn>0014-4851</issn><issn>1741-2765</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2022</creationdate><recordtype>article</recordtype><sourceid>C6C</sourceid><recordid>eNp9kE1LAzEQhoMoWKt_wNOiV1czSXazPUqpH1ARrD2HkMzqlna3ZrKi_npTV_DmaZjheV-Gh7FT4JfAub4iAKl4zgXknFdQ5mqPjUAryIUui3024hxUrqoCDtkR0YqnkNRixJZPSI3v7TpbxIBE2QNa6gNusI2UNW02-4i7LZu1703o2uFedyG7s182-K6ni2xuPzGgzxZbdE0i6Jgd1HZNePI7x2x5M3ue3uXzx9v76fU8d1JBzJ2fFJV33JeCC1Vw5xVYgV76ylcOJ6UGIZSsnJQafQm-rq2tXS2kBqVrkGN2NvR2FBtDronoXl3XtuiigaosuOAJOh-gbejeeqRoVl0f2vSXETpB5URqmSgxUC50RAFrsw3NxoZPA9zsHJvBsUmOzY9jo1JIDiFKcPuC4a_6n9Q3FZN-6g</recordid><startdate>20221001</startdate><enddate>20221001</enddate><creator>Benefiel, B. C.</creator><creator>Larsen, E. D.</creator><creator>Prime, M. B.</creator><creator>Phillips, A. M.</creator><creator>Davies, K. B.</creator><creator>Castano, D.</creator><creator>Cole, J. I.</creator><general>Springer US</general><general>Springer Nature B.V</general><general>Springer</general><scope>C6C</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>OIOZB</scope><scope>OTOTI</scope><orcidid>https://orcid.org/0000-0002-4098-5620</orcidid><orcidid>https://orcid.org/0000000240985620</orcidid></search><sort><creationdate>20221001</creationdate><title>Residual Stress Measurements in Extreme Environments for Hazardous, Layered Specimens</title><author>Benefiel, B. C. ; Larsen, E. D. ; Prime, M. B. ; Phillips, A. M. ; Davies, K. B. ; Castano, D. ; Cole, J. 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C.</creatorcontrib><creatorcontrib>Larsen, E. D.</creatorcontrib><creatorcontrib>Prime, M. B.</creatorcontrib><creatorcontrib>Phillips, A. M.</creatorcontrib><creatorcontrib>Davies, K. B.</creatorcontrib><creatorcontrib>Castano, D.</creatorcontrib><creatorcontrib>Cole, J. I.</creatorcontrib><creatorcontrib>Idaho National Lab. (INL), Idaho Falls, ID (United States)</creatorcontrib><creatorcontrib>Los Alamos National Lab. (LANL), Los Alamos, NM (United States)</creatorcontrib><collection>Springer Nature OA/Free Journals</collection><collection>CrossRef</collection><collection>OSTI.GOV - Hybrid</collection><collection>OSTI.GOV</collection><jtitle>Experimental mechanics</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Benefiel, B. C.</au><au>Larsen, E. D.</au><au>Prime, M. B.</au><au>Phillips, A. M.</au><au>Davies, K. B.</au><au>Castano, D.</au><au>Cole, J. I.</au><aucorp>Idaho National Lab. (INL), Idaho Falls, ID (United States)</aucorp><aucorp>Los Alamos National Lab. (LANL), Los Alamos, NM (United States)</aucorp><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Residual Stress Measurements in Extreme Environments for Hazardous, Layered Specimens</atitle><jtitle>Experimental mechanics</jtitle><stitle>Exp Mech</stitle><date>2022-10-01</date><risdate>2022</risdate><volume>62</volume><issue>8</issue><spage>1381</spage><epage>1400</epage><pages>1381-1400</pages><issn>0014-4851</issn><eissn>1741-2765</eissn><abstract>Background In nuclear fuel plates of low-enriched U-10Mo (LEU) clad with aluminum by hot isostatic pressing (HIP), post-irradiation stresses arising during reactor shutdown are a major concern for safe reactor operations. Measurement of those residual stresses has not previously been possible because the high radioactivity of the plates requires handling only by remote manipulation in a hot cell. Objective The incremental slitting method for measuring through-thickness stress profiles was modified, and a system for automated, remote operation was built and tested. Methods Experimental modifications consisted of replacing electric-discharge machining (EDM) with a small end mill and strain-gauge measurements with cantilever displacement measurements. The inverse method used to calculate stresses was the pulse-regularization method modified to allow discontinuities across material interfaces. The new system was validated by comparing with conventional slitting on a depleted U-10Mo (DU) fuel plate. Results The new system was applied to two measurements each on six as-fabricated (pre-irradiation) LEU miniature fuel plates. Variations between the measurements at two locations in the same plate were strongly correlated with measured geometrical heterogeneity in the plate—a tilt in the fuel foil. Compressive stresses in the U-10Mo were shown to increase from 20 to 250 MPa as the ratio of aluminum thickness to U-10Mo thickness increased causing increased constraint during cooling. Faster cooling rates during processing also increased stress magnitudes. Conclusions The measurements trends agreed with data in the literature from similar plates made with DU, which further validates the method. Because other methods are impractical in a hot cell, the modified slitting method is now poised for the first measurements of post-irradiation stresses.</abstract><cop>New York</cop><pub>Springer US</pub><doi>10.1007/s11340-021-00816-4</doi><tpages>20</tpages><orcidid>https://orcid.org/0000-0002-4098-5620</orcidid><orcidid>https://orcid.org/0000000240985620</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Advances in Residual Stress Technology Aluminum Biomedical Engineering and Bioengineering Characterization and Evaluation of Materials Compressive properties Control Cooling rate Dynamical Systems Electric discharge machining End milling Engineering Extreme environments Foils Hazardous areas Heterogeneity hot cell Hot isostatic pressing incremental slitting Inverse method Irradiation Lasers low enriched uranium MATERIALS SCIENCE Measurement methods nuclear fuel Nuclear fuels Optical Devices Optics Photonics Plates Regularization Regularization methods Residual stress residual stress management Shutdowns Slitting Solid Mechanics Strain gauges Thickness measurement Uranium Uranium base alloys Vibration
title	Residual Stress Measurements in Extreme Environments for Hazardous, Layered Specimens
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