Piping structural design for the ITER thermal shield manifold

Chang Hyun Noh; Wooho Chung; Kwanwoo Nam; Kyoung O. Kang; Jing Do Bae; Jong Kook Cha; Kyoung Kyu Kim; Craig Hamlyn-Harris; Robby Hicks; Namil Her; Chang Hoon Jun

doi:10.1016/j.fusengdes.2015.06.105

Piping structural design for the ITER thermal shield manifold

Chang Hyun Noh, Wooho Chung, Kwanwoo Nam, Kyoung O. Kang, Jing Do Bae, Jong Kook Cha, Kyoung Kyu Kim, Craig Hamlyn-Harris, Robby Hicks, Namil Her, Chang Hoon Jun

Fusion Technology

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

6 Scopus citations

Abstract

The thermal shield (TS) provides the thermal barrier in the ITER tokamak to minimize heat load transferred by thermal radiation from the hot components to the superconducting magnets operating at 4.2 K. The TS is actively cooled by 80 K pressurized helium gas which flows from the cold valve box to the cooling tubes on the TS panels via manifold piping. This paper describes the manifold piping design and analysis for the ITER thermal shield. First, maximum allowable span for the manifold support is calculated based on the simple beam theory. In order to accommodate the thermal contraction in the manifold feeder, a contraction loop is designed and applied. Sequential Quadratic Programming (SQP) method is used to determine the optimized dimensions of the contraction loop to ensure adequate flexibility of manifold pipe. Global structural behavior of the manifold is investigated when the thermal movement of the redundant (un-cooled) pipe is large.

Original language	English
Pages (from-to)	1453-1456
Number of pages	4
Journal	Fusion Engineering and Design
Volume	98-99
DOIs	https://doi.org/10.1016/j.fusengdes.2015.06.105
State	Published - Oct 1 2015

Funding

This work is supported by the Ministry of Science, ICT and Future Planning of Republic of Korea under an ITER Project Contract.

Keywords

Manifold
Piping design
Thermal shield

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10.1016/j.fusengdes.2015.06.105

Cite this

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title = "Piping structural design for the ITER thermal shield manifold",

abstract = "The thermal shield (TS) provides the thermal barrier in the ITER tokamak to minimize heat load transferred by thermal radiation from the hot components to the superconducting magnets operating at 4.2 K. The TS is actively cooled by 80 K pressurized helium gas which flows from the cold valve box to the cooling tubes on the TS panels via manifold piping. This paper describes the manifold piping design and analysis for the ITER thermal shield. First, maximum allowable span for the manifold support is calculated based on the simple beam theory. In order to accommodate the thermal contraction in the manifold feeder, a contraction loop is designed and applied. Sequential Quadratic Programming (SQP) method is used to determine the optimized dimensions of the contraction loop to ensure adequate flexibility of manifold pipe. Global structural behavior of the manifold is investigated when the thermal movement of the redundant (un-cooled) pipe is large.",

keywords = "Manifold, Piping design, Thermal shield",

author = "Noh, \{Chang Hyun\} and Wooho Chung and Kwanwoo Nam and Kang, \{Kyoung O.\} and Bae, \{Jing Do\} and Cha, \{Jong Kook\} and Kim, \{Kyoung Kyu\} and Craig Hamlyn-Harris and Robby Hicks and Namil Her and Jun, \{Chang Hoon\}",

year = "2015",

month = oct,

day = "1",

doi = "10.1016/j.fusengdes.2015.06.105",

language = "English",

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pages = "1453--1456",

journal = "Fusion Engineering and Design",

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T1 - Piping structural design for the ITER thermal shield manifold

AU - Noh, Chang Hyun

AU - Chung, Wooho

AU - Nam, Kwanwoo

AU - Kang, Kyoung O.

AU - Bae, Jing Do

AU - Cha, Jong Kook

AU - Kim, Kyoung Kyu

AU - Hamlyn-Harris, Craig

AU - Hicks, Robby

AU - Her, Namil

AU - Jun, Chang Hoon

PY - 2015/10/1

Y1 - 2015/10/1

N2 - The thermal shield (TS) provides the thermal barrier in the ITER tokamak to minimize heat load transferred by thermal radiation from the hot components to the superconducting magnets operating at 4.2 K. The TS is actively cooled by 80 K pressurized helium gas which flows from the cold valve box to the cooling tubes on the TS panels via manifold piping. This paper describes the manifold piping design and analysis for the ITER thermal shield. First, maximum allowable span for the manifold support is calculated based on the simple beam theory. In order to accommodate the thermal contraction in the manifold feeder, a contraction loop is designed and applied. Sequential Quadratic Programming (SQP) method is used to determine the optimized dimensions of the contraction loop to ensure adequate flexibility of manifold pipe. Global structural behavior of the manifold is investigated when the thermal movement of the redundant (un-cooled) pipe is large.

AB - The thermal shield (TS) provides the thermal barrier in the ITER tokamak to minimize heat load transferred by thermal radiation from the hot components to the superconducting magnets operating at 4.2 K. The TS is actively cooled by 80 K pressurized helium gas which flows from the cold valve box to the cooling tubes on the TS panels via manifold piping. This paper describes the manifold piping design and analysis for the ITER thermal shield. First, maximum allowable span for the manifold support is calculated based on the simple beam theory. In order to accommodate the thermal contraction in the manifold feeder, a contraction loop is designed and applied. Sequential Quadratic Programming (SQP) method is used to determine the optimized dimensions of the contraction loop to ensure adequate flexibility of manifold pipe. Global structural behavior of the manifold is investigated when the thermal movement of the redundant (un-cooled) pipe is large.

KW - Manifold

KW - Piping design

KW - Thermal shield

UR - https://www.scopus.com/pages/publications/84942551691

U2 - 10.1016/j.fusengdes.2015.06.105

DO - 10.1016/j.fusengdes.2015.06.105

M3 - Article

AN - SCOPUS:84942551691

SN - 0920-3796

VL - 98-99

SP - 1453

EP - 1456

JO - Fusion Engineering and Design

JF - Fusion Engineering and Design

ER -

Piping structural design for the ITER thermal shield manifold

Abstract

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Keywords

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