Nuclear challenges and progress in designing stellarator power plants

L. A. El-Guebaly; P. Wilson; D. Henderson; M. Sawan; G. Sviatoslavsky; T. Tautges; R. Slaybaugh; B. Kiedrowski; A. Ibrahim

Nuclear challenges and progress in designing stellarator power plants

L. A. El-Guebaly, P. Wilson, D. Henderson, M. Sawan, G. Sviatoslavsky, T. Tautges, R. Slaybaugh, B. Kiedrowski, A. Ibrahim

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Over the past 2-3 decades, stellarator power plants have been studied in the U.S., Europe, and Japan as an alternate to the mainline magnetic fusion tokamaks, offering steady state operation and eliminating the risk of plasma disruptions. The earlier 1980s studies suggested large stellarators with an average major radius exceeding 20 m. The most recent development of the compact stellarator concept delivered ARIES-CS - a compact stellarator with 7.75 m average major radius, approaching that of tokamaks. For stellarators, the most important engineering parameter that determines the machine size and cost is the minimum distance between the plasma boundary and mid-coil. Accommodating the breeding blanket and necessary shield within this distance to protect the ARIES-CS superconducting magnet represents a challenging task. Selecting the ARIES-CS nuclear and engineering parameters to produce an economic optimum, modeling the complex geometry for 3-D nuclear analysis to confirm the key parameters, and minimizing the radwaste stream received considerable attention during the design process. These engineering design elements combined with advanced physics helped enable the compact stellarator to be a viable concept. This paper provides a brief historical overview of the progress in designing stellarator power plants and a perspective on the successful integration of the nuclear activity into the final ARIES-CS configuration.

Original language	English
Title of host publication	13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007
Pages	171-191
Number of pages	21
State	Published - 2007
Externally published	Yes
Event	13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007 - Istanbul, Turkey Duration: Jun 3 2007 → Jun 8 2007

Publication series

Name	13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007
Volume	1

Conference

Conference	13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007
Country/Territory	Turkey
City	Istanbul
Period	06/3/07 → 06/8/07

Keywords

Fusion power plant
Nuclear analysis
Radwaste management
Stellarator

Cite this

El-Guebaly, L. A., Wilson, P., Henderson, D., Sawan, M., Sviatoslavsky, G., Tautges, T., Slaybaugh, R., Kiedrowski, B., & Ibrahim, A. (2007). Nuclear challenges and progress in designing stellarator power plants. In 13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007 (pp. 171-191). (13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007; Vol. 1).

@inproceedings{fb41a7534a0243f5b0bbc06ebff786c0,

title = "Nuclear challenges and progress in designing stellarator power plants",

abstract = "Over the past 2-3 decades, stellarator power plants have been studied in the U.S., Europe, and Japan as an alternate to the mainline magnetic fusion tokamaks, offering steady state operation and eliminating the risk of plasma disruptions. The earlier 1980s studies suggested large stellarators with an average major radius exceeding 20 m. The most recent development of the compact stellarator concept delivered ARIES-CS - a compact stellarator with 7.75 m average major radius, approaching that of tokamaks. For stellarators, the most important engineering parameter that determines the machine size and cost is the minimum distance between the plasma boundary and mid-coil. Accommodating the breeding blanket and necessary shield within this distance to protect the ARIES-CS superconducting magnet represents a challenging task. Selecting the ARIES-CS nuclear and engineering parameters to produce an economic optimum, modeling the complex geometry for 3-D nuclear analysis to confirm the key parameters, and minimizing the radwaste stream received considerable attention during the design process. These engineering design elements combined with advanced physics helped enable the compact stellarator to be a viable concept. This paper provides a brief historical overview of the progress in designing stellarator power plants and a perspective on the successful integration of the nuclear activity into the final ARIES-CS configuration.",

keywords = "Fusion power plant, Nuclear analysis, Radwaste management, Stellarator",

author = "El-Guebaly, \{L. A.\} and P. Wilson and D. Henderson and M. Sawan and G. Sviatoslavsky and T. Tautges and R. Slaybaugh and B. Kiedrowski and A. Ibrahim",

year = "2007",

language = "English",

isbn = "9781617824760",

series = "13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007",

pages = "171--191",

booktitle = "13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007",

note = "13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007 ; Conference date: 03-06-2007 Through 08-06-2007",

}

El-Guebaly, LA, Wilson, P, Henderson, D, Sawan, M, Sviatoslavsky, G, Tautges, T, Slaybaugh, R, Kiedrowski, B & Ibrahim, A 2007, Nuclear challenges and progress in designing stellarator power plants. in 13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007. 13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007, vol. 1, pp. 171-191, 13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007, Istanbul, Turkey, 06/3/07.

Nuclear challenges and progress in designing stellarator power plants. / El-Guebaly, L. A.; Wilson, P.; Henderson, D. et al.
13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007. 2007. p. 171-191 (13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007; Vol. 1).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Nuclear challenges and progress in designing stellarator power plants

AU - El-Guebaly, L. A.

AU - Wilson, P.

AU - Henderson, D.

AU - Sawan, M.

AU - Sviatoslavsky, G.

AU - Tautges, T.

AU - Slaybaugh, R.

AU - Kiedrowski, B.

AU - Ibrahim, A.

PY - 2007

Y1 - 2007

N2 - Over the past 2-3 decades, stellarator power plants have been studied in the U.S., Europe, and Japan as an alternate to the mainline magnetic fusion tokamaks, offering steady state operation and eliminating the risk of plasma disruptions. The earlier 1980s studies suggested large stellarators with an average major radius exceeding 20 m. The most recent development of the compact stellarator concept delivered ARIES-CS - a compact stellarator with 7.75 m average major radius, approaching that of tokamaks. For stellarators, the most important engineering parameter that determines the machine size and cost is the minimum distance between the plasma boundary and mid-coil. Accommodating the breeding blanket and necessary shield within this distance to protect the ARIES-CS superconducting magnet represents a challenging task. Selecting the ARIES-CS nuclear and engineering parameters to produce an economic optimum, modeling the complex geometry for 3-D nuclear analysis to confirm the key parameters, and minimizing the radwaste stream received considerable attention during the design process. These engineering design elements combined with advanced physics helped enable the compact stellarator to be a viable concept. This paper provides a brief historical overview of the progress in designing stellarator power plants and a perspective on the successful integration of the nuclear activity into the final ARIES-CS configuration.

AB - Over the past 2-3 decades, stellarator power plants have been studied in the U.S., Europe, and Japan as an alternate to the mainline magnetic fusion tokamaks, offering steady state operation and eliminating the risk of plasma disruptions. The earlier 1980s studies suggested large stellarators with an average major radius exceeding 20 m. The most recent development of the compact stellarator concept delivered ARIES-CS - a compact stellarator with 7.75 m average major radius, approaching that of tokamaks. For stellarators, the most important engineering parameter that determines the machine size and cost is the minimum distance between the plasma boundary and mid-coil. Accommodating the breeding blanket and necessary shield within this distance to protect the ARIES-CS superconducting magnet represents a challenging task. Selecting the ARIES-CS nuclear and engineering parameters to produce an economic optimum, modeling the complex geometry for 3-D nuclear analysis to confirm the key parameters, and minimizing the radwaste stream received considerable attention during the design process. These engineering design elements combined with advanced physics helped enable the compact stellarator to be a viable concept. This paper provides a brief historical overview of the progress in designing stellarator power plants and a perspective on the successful integration of the nuclear activity into the final ARIES-CS configuration.

KW - Fusion power plant

KW - Nuclear analysis

KW - Radwaste management

KW - Stellarator

UR - https://www.scopus.com/pages/publications/79959510137

M3 - Conference contribution

AN - SCOPUS:79959510137

SN - 9781617824760

T3 - 13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007

SP - 171

EP - 191

BT - 13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007

T2 - 13th International Conference on Emerging Nuclear Energy Systems 2007, ICENES 2007

Y2 - 3 June 2007 through 8 June 2007

ER -

Nuclear challenges and progress in designing stellarator power plants

Abstract

Publication series

Conference

Keywords

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