Preconceptual Design of Multifunctional Gas-Cooled Cartridge Loop for the Versatile Test Reactor: Instrumentation and Measurement—Part II

Piyush Sabharwall; Kevan Weaver; N. K. Anand; Chris Ellis; Xiaodong Sun; Hangbok Choi; Di Chen; Rich Christensen; Brian M. Fronk; Joshua Gess; Yassin Hassan; Igor Jovanovic; Annalisa Manera; Victor Petrov; Rodolfo Vaghetto; Silvino Balderrama-Prieto; Adam J. Burak; Milos Burger; Alberto Cardenas-Melgar; Daniel Orea; Reynaldo Chavez; Byunghee Choi; Londrea Garrett; Genevieve L. Gaudin; Noah Sutton; Ken Willams; Josh Young

doi:10.1080/00295639.2022.2070384

Preconceptual Design of Multifunctional Gas-Cooled Cartridge Loop for the Versatile Test Reactor: Instrumentation and Measurement—Part II

Piyush Sabharwall
, Kevan Weaver
, N. K. Anand
, Chris Ellis
, Xiaodong Sun
, Hangbok Choi
, Di Chen
, Rich Christensen
, Brian M. Fronk
, Joshua Gess
, Yassin Hassan
, Igor Jovanovic
, Annalisa Manera
, Victor Petrov
, Rodolfo Vaghetto
, Silvino Balderrama-Prieto
, Adam J. Burak
, Milos Burger
, Alberto Cardenas-Melgar
, Daniel Orea

Reynaldo Chavez, Byunghee Choi, Londrea Garrett, Genevieve L. Gaudin, Noah Sutton, Ken Willams, Josh Young

Research output: Contribution to journal › Article › peer-review

8 Scopus citations

Abstract

An integrated effort by the Versatile Test Reactor (VTR) Gas-Cooled Fast Reactor (GFR) Team to develop an experiment vehicle or extended-length test assembly for the VTR experiments is led by Idaho National Laboratory and supported by an industrial partner, General Atomics, and university partners, including Texas A&M University, University of Michigan, Oregon State University, University of Houston, and University of Idaho. The focus of the effort is to design a helium gas-cooled cartridge loop (GCL) to assist with the testing of fuels, materials, and instrumentation to further support development of advanced reactor systems. This study is divided into two parts. Part I provides the functional requirements and critical irradiation data needs for advancing gas-cooled fast reactor (GFR) technologies. The objective of Part I is to describe the overall preliminary conceptual design of the VTR helium cartridge loop, the design of a fission product venting system, thermal-hydraulic effects of flow direction, and gamma-heating generation in the cartridge. This paper, Part II, includes the measurement techniques being developed to measure the thermophysical properties of the different materials that make up the GCL, as well as the instrumentation and control system within the cartridge required for advancing GFR technologies. The purpose of Part II is to describe the functionality and efficacy of the measuring systems being developed to support the GCL. These systems include (a) a unique measurement platform that joins ion irradiation and a laser beam with an infrared camera and X-ray detection equipment developed and used to investigate more accurately and efficiently the influence of radiation and fission gases on the material properties under high temperatures; (b) a laser-induced breakdown spectroscopy to demonstrate its capability of monitoring possible fuel failure by detecting sub–part-per-million levels of xenon in the helium coolant stream, providing experimental data to better understand the interactions of fuel elements and coolant at high temperature, pressure, and fast neutron flux; (c) fiber-optic sensors with the ability to measure both the temperature demonstrated using a three-dimensional printed heat exchanger and, potentially, the strain in harsh environments; and (d) surface emissivity measurement test rigs to understand the effect of temperature, radiation, and surface finish on the silicon carbide cladding surface emissivity. Additional analyses and development, as well as integrated out-of-pile testing, are planned to demonstrate and validate the accuracy of the measuring systems and instrumentation in a more prototypic environment prior to their implementation into the VTR.

Original language	English
Pages (from-to)	215-233
Number of pages	19
Journal	Nuclear Science and Engineering
Volume	196
Issue number	sup1
DOIs	https://doi.org/10.1080/00295639.2022.2070384
State	Published - 2022
Externally published	Yes

Funding

The submitted document has been created by Battelle Energy Alliance, LLC, Operator of INL. INL’s work was supported by the U.S. Department of Energy, Office of Nuclear Energy under contract number DE-AC07-05ID14517. The work reported in this paper is the result of ongoing efforts supporting the VTR. This work was supported by the Idaho National Laboratory [UNSE-2022-C7433]. The submitted document has been created by Battelle Energy Alliance, LLC, Operator of INL. INL’s work was supported by the U.S. Department of Energy, Office of Nuclear Energy under contract number DE-AC07-05ID14517. The work reported in this paper is the result of ongoing efforts supporting the VTR.

Keywords

Versatile Test Reactor
gas-cooled fast reactor
helium gas-cooled cartridge loop
preliminary conceptual design
thermophysical properties

Access to Document

10.1080/00295639.2022.2070384

Cite this

Sabharwall, P., Weaver, K., Anand, N. K., Ellis, C., Sun, X., Choi, H., Chen, D., Christensen, R., Fronk, B. M., Gess, J., Hassan, Y., Jovanovic, I., Manera, A., Petrov, V., Vaghetto, R., Balderrama-Prieto, S., Burak, A. J., Burger, M., Cardenas-Melgar, A., ... Young, J. (2022). Preconceptual Design of Multifunctional Gas-Cooled Cartridge Loop for the Versatile Test Reactor: Instrumentation and Measurement—Part II. Nuclear Science and Engineering, 196(sup1), 215-233. https://doi.org/10.1080/00295639.2022.2070384

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title = "Preconceptual Design of Multifunctional Gas-Cooled Cartridge Loop for the Versatile Test Reactor: Instrumentation and Measurement—Part II",

abstract = "An integrated effort by the Versatile Test Reactor (VTR) Gas-Cooled Fast Reactor (GFR) Team to develop an experiment vehicle or extended-length test assembly for the VTR experiments is led by Idaho National Laboratory and supported by an industrial partner, General Atomics, and university partners, including Texas A\&M University, University of Michigan, Oregon State University, University of Houston, and University of Idaho. The focus of the effort is to design a helium gas-cooled cartridge loop (GCL) to assist with the testing of fuels, materials, and instrumentation to further support development of advanced reactor systems. This study is divided into two parts. Part I provides the functional requirements and critical irradiation data needs for advancing gas-cooled fast reactor (GFR) technologies. The objective of Part I is to describe the overall preliminary conceptual design of the VTR helium cartridge loop, the design of a fission product venting system, thermal-hydraulic effects of flow direction, and gamma-heating generation in the cartridge. This paper, Part II, includes the measurement techniques being developed to measure the thermophysical properties of the different materials that make up the GCL, as well as the instrumentation and control system within the cartridge required for advancing GFR technologies. The purpose of Part II is to describe the functionality and efficacy of the measuring systems being developed to support the GCL. These systems include (a) a unique measurement platform that joins ion irradiation and a laser beam with an infrared camera and X-ray detection equipment developed and used to investigate more accurately and efficiently the influence of radiation and fission gases on the material properties under high temperatures; (b) a laser-induced breakdown spectroscopy to demonstrate its capability of monitoring possible fuel failure by detecting sub–part-per-million levels of xenon in the helium coolant stream, providing experimental data to better understand the interactions of fuel elements and coolant at high temperature, pressure, and fast neutron flux; (c) fiber-optic sensors with the ability to measure both the temperature demonstrated using a three-dimensional printed heat exchanger and, potentially, the strain in harsh environments; and (d) surface emissivity measurement test rigs to understand the effect of temperature, radiation, and surface finish on the silicon carbide cladding surface emissivity. Additional analyses and development, as well as integrated out-of-pile testing, are planned to demonstrate and validate the accuracy of the measuring systems and instrumentation in a more prototypic environment prior to their implementation into the VTR.",

keywords = "Versatile Test Reactor, gas-cooled fast reactor, helium gas-cooled cartridge loop, preliminary conceptual design, thermophysical properties",

author = "Piyush Sabharwall and Kevan Weaver and Anand, \{N. K.\} and Chris Ellis and Xiaodong Sun and Hangbok Choi and Di Chen and Rich Christensen and Fronk, \{Brian M.\} and Joshua Gess and Yassin Hassan and Igor Jovanovic and Annalisa Manera and Victor Petrov and Rodolfo Vaghetto and Silvino Balderrama-Prieto and Burak, \{Adam J.\} and Milos Burger and Alberto Cardenas-Melgar and Daniel Orea and Reynaldo Chavez and Byunghee Choi and Londrea Garrett and Gaudin, \{Genevieve L.\} and Noah Sutton and Ken Willams and Josh Young",

note = "Publisher Copyright: {\textcopyright} 2022 The Author(s). Published with license by Taylor \& Francis Group, LLC.",

year = "2022",

doi = "10.1080/00295639.2022.2070384",

language = "English",

volume = "196",

pages = "215--233",

journal = "Nuclear Science and Engineering",

issn = "0029-5639",

publisher = "Taylor and Francis Group",

number = "sup1",

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Sabharwall, P, Weaver, K, Anand, NK, Ellis, C, Sun, X, Choi, H, Chen, D, Christensen, R, Fronk, BM, Gess, J, Hassan, Y, Jovanovic, I, Manera, A, Petrov, V, Vaghetto, R, Balderrama-Prieto, S, Burak, AJ, Burger, M, Cardenas-Melgar, A, Orea, D, Chavez, R, Choi, B, Garrett, L, Gaudin, GL, Sutton, N, Willams, K & Young, J 2022, 'Preconceptual Design of Multifunctional Gas-Cooled Cartridge Loop for the Versatile Test Reactor: Instrumentation and Measurement—Part II', Nuclear Science and Engineering, vol. 196, no. sup1, pp. 215-233. https://doi.org/10.1080/00295639.2022.2070384

TY - JOUR

T1 - Preconceptual Design of Multifunctional Gas-Cooled Cartridge Loop for the Versatile Test Reactor

T2 - Instrumentation and Measurement—Part II

AU - Sabharwall, Piyush

AU - Weaver, Kevan

AU - Anand, N. K.

AU - Ellis, Chris

AU - Sun, Xiaodong

AU - Choi, Hangbok

AU - Chen, Di

AU - Christensen, Rich

AU - Fronk, Brian M.

AU - Gess, Joshua

AU - Hassan, Yassin

AU - Jovanovic, Igor

AU - Manera, Annalisa

AU - Petrov, Victor

AU - Vaghetto, Rodolfo

AU - Balderrama-Prieto, Silvino

AU - Burak, Adam J.

AU - Burger, Milos

AU - Cardenas-Melgar, Alberto

AU - Orea, Daniel

AU - Chavez, Reynaldo

AU - Choi, Byunghee

AU - Garrett, Londrea

AU - Gaudin, Genevieve L.

AU - Sutton, Noah

AU - Willams, Ken

AU - Young, Josh

PY - 2022

Y1 - 2022

N2 - An integrated effort by the Versatile Test Reactor (VTR) Gas-Cooled Fast Reactor (GFR) Team to develop an experiment vehicle or extended-length test assembly for the VTR experiments is led by Idaho National Laboratory and supported by an industrial partner, General Atomics, and university partners, including Texas A&M University, University of Michigan, Oregon State University, University of Houston, and University of Idaho. The focus of the effort is to design a helium gas-cooled cartridge loop (GCL) to assist with the testing of fuels, materials, and instrumentation to further support development of advanced reactor systems. This study is divided into two parts. Part I provides the functional requirements and critical irradiation data needs for advancing gas-cooled fast reactor (GFR) technologies. The objective of Part I is to describe the overall preliminary conceptual design of the VTR helium cartridge loop, the design of a fission product venting system, thermal-hydraulic effects of flow direction, and gamma-heating generation in the cartridge. This paper, Part II, includes the measurement techniques being developed to measure the thermophysical properties of the different materials that make up the GCL, as well as the instrumentation and control system within the cartridge required for advancing GFR technologies. The purpose of Part II is to describe the functionality and efficacy of the measuring systems being developed to support the GCL. These systems include (a) a unique measurement platform that joins ion irradiation and a laser beam with an infrared camera and X-ray detection equipment developed and used to investigate more accurately and efficiently the influence of radiation and fission gases on the material properties under high temperatures; (b) a laser-induced breakdown spectroscopy to demonstrate its capability of monitoring possible fuel failure by detecting sub–part-per-million levels of xenon in the helium coolant stream, providing experimental data to better understand the interactions of fuel elements and coolant at high temperature, pressure, and fast neutron flux; (c) fiber-optic sensors with the ability to measure both the temperature demonstrated using a three-dimensional printed heat exchanger and, potentially, the strain in harsh environments; and (d) surface emissivity measurement test rigs to understand the effect of temperature, radiation, and surface finish on the silicon carbide cladding surface emissivity. Additional analyses and development, as well as integrated out-of-pile testing, are planned to demonstrate and validate the accuracy of the measuring systems and instrumentation in a more prototypic environment prior to their implementation into the VTR.

AB - An integrated effort by the Versatile Test Reactor (VTR) Gas-Cooled Fast Reactor (GFR) Team to develop an experiment vehicle or extended-length test assembly for the VTR experiments is led by Idaho National Laboratory and supported by an industrial partner, General Atomics, and university partners, including Texas A&M University, University of Michigan, Oregon State University, University of Houston, and University of Idaho. The focus of the effort is to design a helium gas-cooled cartridge loop (GCL) to assist with the testing of fuels, materials, and instrumentation to further support development of advanced reactor systems. This study is divided into two parts. Part I provides the functional requirements and critical irradiation data needs for advancing gas-cooled fast reactor (GFR) technologies. The objective of Part I is to describe the overall preliminary conceptual design of the VTR helium cartridge loop, the design of a fission product venting system, thermal-hydraulic effects of flow direction, and gamma-heating generation in the cartridge. This paper, Part II, includes the measurement techniques being developed to measure the thermophysical properties of the different materials that make up the GCL, as well as the instrumentation and control system within the cartridge required for advancing GFR technologies. The purpose of Part II is to describe the functionality and efficacy of the measuring systems being developed to support the GCL. These systems include (a) a unique measurement platform that joins ion irradiation and a laser beam with an infrared camera and X-ray detection equipment developed and used to investigate more accurately and efficiently the influence of radiation and fission gases on the material properties under high temperatures; (b) a laser-induced breakdown spectroscopy to demonstrate its capability of monitoring possible fuel failure by detecting sub–part-per-million levels of xenon in the helium coolant stream, providing experimental data to better understand the interactions of fuel elements and coolant at high temperature, pressure, and fast neutron flux; (c) fiber-optic sensors with the ability to measure both the temperature demonstrated using a three-dimensional printed heat exchanger and, potentially, the strain in harsh environments; and (d) surface emissivity measurement test rigs to understand the effect of temperature, radiation, and surface finish on the silicon carbide cladding surface emissivity. Additional analyses and development, as well as integrated out-of-pile testing, are planned to demonstrate and validate the accuracy of the measuring systems and instrumentation in a more prototypic environment prior to their implementation into the VTR.

KW - Versatile Test Reactor

KW - gas-cooled fast reactor

KW - helium gas-cooled cartridge loop

KW - preliminary conceptual design

KW - thermophysical properties

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DO - 10.1080/00295639.2022.2070384

M3 - Article

AN - SCOPUS:85133723678

SN - 0029-5639

VL - 196

SP - 215

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JO - Nuclear Science and Engineering

JF - Nuclear Science and Engineering

IS - sup1

ER -

Preconceptual Design of Multifunctional Gas-Cooled Cartridge Loop for the Versatile Test Reactor: Instrumentation and Measurement—Part II

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