Thermomechanical behaviour of actively cooled divertor elements with internal coolant flow return

Michael Scheerer; H. Bolt; J. Linke; R. Lison; H. Sauer; Ivica Smid; R. Uhlemann

Thermomechanical behaviour of actively cooled divertor elements with internal coolant flow return

Michael Scheerer
, H. Bolt
, J. Linke
, R. Lison
, H. Sauer
, Ivica Smid
, R. Uhlemann

Forschungszentrum Jülich GmbH

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

Abstract

For future fusion devices, target element specimens with a reversal of the coolant flow have been designed, manufactured and tested. Two parallel OFHC-Cu tubes connected with another at one end by a Cu flow reversal element brazed onto blocks of a 2-D Carbon Fiber reinforced Carbon (CFC) have been selected to realize such divertor elements. To estimate the thermal behaviour, heat load experiments were performed in the high heat flux ion beam facility MARION. Peak power densities up to 13 MW/M2 for 5, 10 and 20s of the elliptic Gaussian shaped hydrogen ion beam have been applied to the target element specimens. After extreme heat loads, cracks in the 2-D CFC black occured leading to a strong deformation of the CFC and a partial dtachment of the Cu tubes. By using a castellated CFC materials and a large number of braze depots for the target elements no cracking of the CFC material took place and a good thermal performance up to power loads of more than 10 MW/m2 has been achieved.

Original language	English
Pages (from-to)	6
Number of pages	6
Journal	Fusion Engineering and Design
Volume	0
Publication status	Published - 2000

Research Field

Not defined

Cite this

@article{2fbcecb1b3cd4c409bd9396eb2cc5f98,

title = "Thermomechanical behaviour of actively cooled divertor elements with internal coolant flow return",

abstract = "For future fusion devices, target element specimens with a reversal of the coolant flow have been designed, manufactured and tested. Two parallel OFHC-Cu tubes connected with another at one end by a Cu flow reversal element brazed onto blocks of a 2-D Carbon Fiber reinforced Carbon (CFC) have been selected to realize such divertor elements. To estimate the thermal behaviour, heat load experiments were performed in the high heat flux ion beam facility MARION. Peak power densities up to 13 MW/M2 for 5, 10 and 20s of the elliptic Gaussian shaped hydrogen ion beam have been applied to the target element specimens. After extreme heat loads, cracks in the 2-D CFC black occured leading to a strong deformation of the CFC and a partial dtachment of the Cu tubes. By using a castellated CFC materials and a large number of braze depots for the target elements no cracking of the CFC material took place and a good thermal performance up to power loads of more than 10 MW/m2 has been achieved.",

author = "Michael Scheerer and H. Bolt and J. Linke and R. Lison and H. Sauer and Ivica Smid and R. Uhlemann",

year = "2000",

language = "English",

volume = "0",

pages = "6",

journal = "Fusion Engineering and Design",

issn = "0920-3796",

publisher = "Elsevier BV",

}

TY - JOUR

T1 - Thermomechanical behaviour of actively cooled divertor elements with internal coolant flow return

AU - Scheerer, Michael

AU - Bolt, H.

AU - Linke, J.

AU - Lison, R.

AU - Sauer, H.

AU - Smid, Ivica

AU - Uhlemann, R.

PY - 2000

Y1 - 2000

N2 - For future fusion devices, target element specimens with a reversal of the coolant flow have been designed, manufactured and tested. Two parallel OFHC-Cu tubes connected with another at one end by a Cu flow reversal element brazed onto blocks of a 2-D Carbon Fiber reinforced Carbon (CFC) have been selected to realize such divertor elements. To estimate the thermal behaviour, heat load experiments were performed in the high heat flux ion beam facility MARION. Peak power densities up to 13 MW/M2 for 5, 10 and 20s of the elliptic Gaussian shaped hydrogen ion beam have been applied to the target element specimens. After extreme heat loads, cracks in the 2-D CFC black occured leading to a strong deformation of the CFC and a partial dtachment of the Cu tubes. By using a castellated CFC materials and a large number of braze depots for the target elements no cracking of the CFC material took place and a good thermal performance up to power loads of more than 10 MW/m2 has been achieved.

AB - For future fusion devices, target element specimens with a reversal of the coolant flow have been designed, manufactured and tested. Two parallel OFHC-Cu tubes connected with another at one end by a Cu flow reversal element brazed onto blocks of a 2-D Carbon Fiber reinforced Carbon (CFC) have been selected to realize such divertor elements. To estimate the thermal behaviour, heat load experiments were performed in the high heat flux ion beam facility MARION. Peak power densities up to 13 MW/M2 for 5, 10 and 20s of the elliptic Gaussian shaped hydrogen ion beam have been applied to the target element specimens. After extreme heat loads, cracks in the 2-D CFC black occured leading to a strong deformation of the CFC and a partial dtachment of the Cu tubes. By using a castellated CFC materials and a large number of braze depots for the target elements no cracking of the CFC material took place and a good thermal performance up to power loads of more than 10 MW/m2 has been achieved.

M3 - Article

SN - 0920-3796

VL - 0

SP - 6

JO - Fusion Engineering and Design

JF - Fusion Engineering and Design

ER -

Thermomechanical behaviour of actively cooled divertor elements with internal coolant flow return

Abstract

Research Field

Fingerprint

Cite this