skip to main content
OSTI.GOV title logo U.S. Department of Energy
Office of Scientific and Technical Information

Title: Influence of LOTUS concrete structure, boron-loaded sheets, and B[sub 4]C filter on the integral tritium production of a nature lithium graphite-reflected blanket and comparison with experiment

Abstract

Integral tritium production rate (TPR) measurements are important in comparisons of calculations to ascertain the suitability of computer codes and cross-section sets used in calculation. At the LOTUS facility, one of the objectives is to make measurements with different types of pure fusion and hybrid blankets and compare the results with calculations. Since the concrete cavity housing the blankets is small, it is of direct relevance to determine the influence of room-reflected neutrons on the integral TPR and, if possible, to reduce this effect by special absorbers. The effects on the TPR of a stainless steel-natural lithium-graphite-reflected blanket due to the concrete structure, B[sub 4]C filter, and boron-loaded sheets covering the assembly are studied. Calculations are performed by the MCNP Monte Carlo code. Since the room-returned component depends strongly on the composition of the concrete and, more-over, does not correspond to a real blanket situation, it is advisable to compare measurements with calculations for the region where such interference is minimal. A central region is identified for the purpose of comparison. In addition to calculations for a fully homogenized blanket, the important central blanket region is considered in the form of rods, and the remaining blanket as a homogeneous region,more » to assess the effect of neutron streaming on the TPR of the assembly. An experiment is done by irradiating several Li[sub 2]CO[sub 3] probes positioned in each tube so that the central region of interest is fully covered. The activity of the probes is measured by the standard liquid scintillation method, and the TPR for the entire region can be derived from the experimental reaction rate data. The complete details of the calculational model and the experimental procedure are provided. Good agreement is found between the calculated and experimental TPRs after accounting for various sources of errors. 14 refs., 6 figs., 4 tabs.« less

Authors:
;  [1];  [2]
  1. Ecole Polytechnique Federale de Lausanne, Lausanne (Switzerland)
  2. Bhabha Atomic Research Centre, Bombay (India)
Publication Date:
OSTI Identifier:
7020843
Resource Type:
Journal Article
Journal Name:
Fusion Technology; (United States)
Additional Journal Information:
Journal Volume: 23:4; Journal ID: ISSN 0748-1896
Country of Publication:
United States
Language:
English
Subject:
70 PLASMA PHYSICS AND FUSION TECHNOLOGY; BREEDING BLANKETS; COMPUTERIZED SIMULATION; TESTING; NEUTRONS; REFLECTION; LOTUS FACILITY; M CODES; TRITIUM; BARYONS; BETA DECAY RADIOISOTOPES; BETA-MINUS DECAY RADIOISOTOPES; COMPUTER CODES; ELEMENTARY PARTICLES; FERMIONS; HADRONS; HYDROGEN ISOTOPES; ISOTOPES; LIGHT NUCLEI; NUCLEI; NUCLEONS; ODD-EVEN NUCLEI; RADIOISOTOPES; REACTOR COMPONENTS; SIMULATION; YEARS LIVING RADIOISOTOPES; 700450* - Fusion Technology- Blankets & Cooling Systems- (1992-)

Citation Formats

Joneja, O P, Schneeberger, J P, and Nargundkar, V R. Influence of LOTUS concrete structure, boron-loaded sheets, and B[sub 4]C filter on the integral tritium production of a nature lithium graphite-reflected blanket and comparison with experiment. United States: N. p., 1993. Web.
Joneja, O P, Schneeberger, J P, & Nargundkar, V R. Influence of LOTUS concrete structure, boron-loaded sheets, and B[sub 4]C filter on the integral tritium production of a nature lithium graphite-reflected blanket and comparison with experiment. United States.
Joneja, O P, Schneeberger, J P, and Nargundkar, V R. 1993. "Influence of LOTUS concrete structure, boron-loaded sheets, and B[sub 4]C filter on the integral tritium production of a nature lithium graphite-reflected blanket and comparison with experiment". United States.
@article{osti_7020843,
title = {Influence of LOTUS concrete structure, boron-loaded sheets, and B[sub 4]C filter on the integral tritium production of a nature lithium graphite-reflected blanket and comparison with experiment},
author = {Joneja, O P and Schneeberger, J P and Nargundkar, V R},
abstractNote = {Integral tritium production rate (TPR) measurements are important in comparisons of calculations to ascertain the suitability of computer codes and cross-section sets used in calculation. At the LOTUS facility, one of the objectives is to make measurements with different types of pure fusion and hybrid blankets and compare the results with calculations. Since the concrete cavity housing the blankets is small, it is of direct relevance to determine the influence of room-reflected neutrons on the integral TPR and, if possible, to reduce this effect by special absorbers. The effects on the TPR of a stainless steel-natural lithium-graphite-reflected blanket due to the concrete structure, B[sub 4]C filter, and boron-loaded sheets covering the assembly are studied. Calculations are performed by the MCNP Monte Carlo code. Since the room-returned component depends strongly on the composition of the concrete and, more-over, does not correspond to a real blanket situation, it is advisable to compare measurements with calculations for the region where such interference is minimal. A central region is identified for the purpose of comparison. In addition to calculations for a fully homogenized blanket, the important central blanket region is considered in the form of rods, and the remaining blanket as a homogeneous region, to assess the effect of neutron streaming on the TPR of the assembly. An experiment is done by irradiating several Li[sub 2]CO[sub 3] probes positioned in each tube so that the central region of interest is fully covered. The activity of the probes is measured by the standard liquid scintillation method, and the TPR for the entire region can be derived from the experimental reaction rate data. The complete details of the calculational model and the experimental procedure are provided. Good agreement is found between the calculated and experimental TPRs after accounting for various sources of errors. 14 refs., 6 figs., 4 tabs.},
doi = {},
url = {https://www.osti.gov/biblio/7020843}, journal = {Fusion Technology; (United States)},
issn = {0748-1896},
number = ,
volume = 23:4,
place = {United States},
year = {Thu Jul 01 00:00:00 EDT 1993},
month = {Thu Jul 01 00:00:00 EDT 1993}
}