Friction factor estimation for turbulent flows in corrugated pipes with rough walls

Non-metallic flexible pipes are widely used in industry. They are comprised of fabric wrapped over a spiral metal framework. Due to this construction, they respond very well to bending and they are cheaper and much easier to install than metal pipes. Because of the specific construction, the pipe wa...

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Main Authors:	Pisarenco, M., Linden, van der, B.J., Tijsseling, A.S., Ory, E., Dam, J.A.M.
Format:	Other Non-Article Part of Journal/Newspaper
Language:	English
Published:	American Society of Mechanical Engineers 2009
Subjects:	Arctic
Online Access:	https://research.tue.nl/en/publications/7574b652-0114-4b90-b7df-3ba6e9b0a34f

id	ftuniveindcris:oai:pure.tue.nl:publications/7574b652-0114-4b90-b7df-3ba6e9b0a34f
record_format	openpolar
spelling	ftuniveindcris:oai:pure.tue.nl:publications/7574b652-0114-4b90-b7df-3ba6e9b0a34f 2023-05-15T14:26:26+02:00 Friction factor estimation for turbulent flows in corrugated pipes with rough walls Pisarenco, M. Linden, van der, B.J. Tijsseling, A.S. Ory, E. Dam, J.A.M. 2009 https://research.tue.nl/en/publications/7574b652-0114-4b90-b7df-3ba6e9b0a34f eng eng American Society of Mechanical Engineers info:eu-repo/semantics/closedAccess Pisarenco , M , Linden, van der , B J , Tijsseling , A S , Ory , E & Dam , J A M 2009 , Friction factor estimation for turbulent flows in corrugated pipes with rough walls . in Proceedings of the ASME 28th International Conference on Ocean Offshore and Arctic Engineering (Honolulu HI, USA, May 31-June 5, 2009) . American Society of Mechanical Engineers , pp. OMAE2009-79854- . contributionToPeriodical 2009 ftuniveindcris 2022-02-18T14:30:15Z Non-metallic flexible pipes are widely used in industry. They are comprised of fabric wrapped over a spiral metal framework. Due to this construction, they respond very well to bending and they are cheaper and much easier to install than metal pipes. Because of the specific construction, the pipe walls are corrugated and the fabric which covers the steel spiral is much rougher than the wall of a metal pipe. In this investigation we are interested in estimating the friction factor for the flow in this type of pipes. Two-equation turbulence models (k -?? and k -!) are used in the computations. The process of deriving these models is presented first. Then we look at turbulent boundary layers and the law of the wall which gives the velocity profile near the wall. Its use as a boundary condition is explained. After the theoretical ideas have been exposed, we look at fully developed turbulent flow in a conventional pipe. Simulations are performed to validate the chosen models, boundary conditions and computational grids. Then a new boundary condition is implemented based on the "combined" law of the wall. It enables us to model the effects of roughness. The new boundary condition is validated by performing simulations of turbulent flow in rough pipes and comparing the computed friction factor to the one given by the Moody diagram. Finally, turbulent flow in periodically corrugated (flexible) pipes is considered. New flow phenomena (such as flow separation) caused by the corrugation are pointed out and the essence of periodically fully developed flow is explained. The friction factor for different values of relative roughness of the fabric is estimated by performing a series of simulations. Conclusions are drawn based on the results of the computations. Some of them are that the k - ?? model performs slightly better than the k - ! model in predicting both regular and separated flow and that the friction factor in a flexible corrugated pipe is mostly determined by the shape and size of the steel spiral, and not by the type of the fabric which is wrapped around the spiral. Other Non-Article Part of Journal/Newspaper Arctic Eindhoven University of Technology research portal
institution	Open Polar
collection	Eindhoven University of Technology research portal
op_collection_id	ftuniveindcris
language	English
description	Non-metallic flexible pipes are widely used in industry. They are comprised of fabric wrapped over a spiral metal framework. Due to this construction, they respond very well to bending and they are cheaper and much easier to install than metal pipes. Because of the specific construction, the pipe walls are corrugated and the fabric which covers the steel spiral is much rougher than the wall of a metal pipe. In this investigation we are interested in estimating the friction factor for the flow in this type of pipes. Two-equation turbulence models (k -?? and k -!) are used in the computations. The process of deriving these models is presented first. Then we look at turbulent boundary layers and the law of the wall which gives the velocity profile near the wall. Its use as a boundary condition is explained. After the theoretical ideas have been exposed, we look at fully developed turbulent flow in a conventional pipe. Simulations are performed to validate the chosen models, boundary conditions and computational grids. Then a new boundary condition is implemented based on the "combined" law of the wall. It enables us to model the effects of roughness. The new boundary condition is validated by performing simulations of turbulent flow in rough pipes and comparing the computed friction factor to the one given by the Moody diagram. Finally, turbulent flow in periodically corrugated (flexible) pipes is considered. New flow phenomena (such as flow separation) caused by the corrugation are pointed out and the essence of periodically fully developed flow is explained. The friction factor for different values of relative roughness of the fabric is estimated by performing a series of simulations. Conclusions are drawn based on the results of the computations. Some of them are that the k - ?? model performs slightly better than the k - ! model in predicting both regular and separated flow and that the friction factor in a flexible corrugated pipe is mostly determined by the shape and size of the steel spiral, and not by the type of the fabric which is wrapped around the spiral.
format	Other Non-Article Part of Journal/Newspaper
author	Pisarenco, M. Linden, van der, B.J. Tijsseling, A.S. Ory, E. Dam, J.A.M.
spellingShingle	Pisarenco, M. Linden, van der, B.J. Tijsseling, A.S. Ory, E. Dam, J.A.M. Friction factor estimation for turbulent flows in corrugated pipes with rough walls
author_facet	Pisarenco, M. Linden, van der, B.J. Tijsseling, A.S. Ory, E. Dam, J.A.M.
author_sort	Pisarenco, M.
title	Friction factor estimation for turbulent flows in corrugated pipes with rough walls
title_short	Friction factor estimation for turbulent flows in corrugated pipes with rough walls
title_full	Friction factor estimation for turbulent flows in corrugated pipes with rough walls
title_fullStr	Friction factor estimation for turbulent flows in corrugated pipes with rough walls
title_full_unstemmed	Friction factor estimation for turbulent flows in corrugated pipes with rough walls
title_sort	friction factor estimation for turbulent flows in corrugated pipes with rough walls
publisher	American Society of Mechanical Engineers
publishDate	2009
url	https://research.tue.nl/en/publications/7574b652-0114-4b90-b7df-3ba6e9b0a34f
genre	Arctic
genre_facet	Arctic
op_source	Pisarenco , M , Linden, van der , B J , Tijsseling , A S , Ory , E & Dam , J A M 2009 , Friction factor estimation for turbulent flows in corrugated pipes with rough walls . in Proceedings of the ASME 28th International Conference on Ocean Offshore and Arctic Engineering (Honolulu HI, USA, May 31-June 5, 2009) . American Society of Mechanical Engineers , pp. OMAE2009-79854- .
op_rights	info:eu-repo/semantics/closedAccess
_version_	1766298999258611712

Friction factor estimation for turbulent flows in corrugated pipes with rough walls

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