CERN Accelerating science

Article
Title Manufacturing technologies and joining methods of metallic thin-walled pipes for use in high pressure cooling systems
Author(s) McNair, Sophie A M (Bath U.) ; Chaharsooghi, Alborz Shokrani (Bath U.) ; Carnevale, Mauro (Bath U.) ; Rhead, Andrew (Bath U.) ; Onnela, Antti (CERN) ; Daguin, Jerome (CERN) ; Cichy, Kamil (CERN) ; Postema, Hans (Cornell U.) ; Bacchetta, Nicola (CERN) ; French, Thomas (CERN) ; Lunt, Alexander J G (Bath U.)
Publication 2021
Number of pages 15
In: Int. J. Adv. Manuf. Technol. 118 (2021) 667-681
DOI 10.1007/s00170-021-07982-8
Subject category Detectors and Experimental Techniques ; Accelerators and Storage Rings
Abstract Small diameter thin-walled pipes, typically with a diameter less than 20 mm and a ratio of outer diameter to wall thickness is 20 or above, have increasingly become a key value adding factor for a number of industries including medical applications, electronics and chemical industries. In high-energy physics experiments, thin-walled pipes are needed in tracking detector cooling systems where the mass of all components needs to be minimised for physics measurement reasons. The pipework must reliably withstand the cooling fluid operation pressures (of up to 100 bar), but must also be able to be reliably and easily joined within the cooling system. Suitable standard and/or commercial solutions combining the needed low mass and reliable high-pressure operation are poorly available. The following review of literature compares the various techniques that exist for the manufacture and joining of thin-walled pipes, both well-established techniques and novel methods which have potential to increase the use of thin-walled pipes within industrial cooling systems. Gaps in knowledge have been identified, along with further research directions. Operational challenges and key considerations which have to be identified when designing a system which uses thin-walled pipes are also discussed.
Copyright/License © 2021-2024 The Author(s) (License: CC-BY-4.0)

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 Record created 2022-05-17, last modified 2022-05-19


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