Publication detail
Intensification of heat transfer of polymeric hollow fiber heat exchangers by chaotisation
RAUDENSKÝ, M. ASTROUSKI, I. DOHNAL, M.
English title
Intensification of heat transfer of polymeric hollow fiber heat exchangers by chaotisation
Type
journal article in Web of Science
Language
en
Original abstract
Flexible polymeric hollow fibers are used as heat transfer elements. A potted bundle of several hundred such fibers can be used as a heat exchanger in different ways. The simplest application is a submerged bundle. The fibers studied in this paper have outside diameters below 0.8 mm. Such very small-diameter polymer fibers significantly facilitate heat transfer. However, these potted sets of fibers must be designed to guarantee that all fibers are in direct contact with the surrounding stream of fluid. It is possible to use textile technologies to keep fibers strictly parallel and separated. However, a parallel arrangement can be expensive and is not flexible. A low-cost variant utilizes bundle chaotisation, which means that each fiber has a unique shape. The consequence is that their mutual mechanical contacts are point-wise. Several methods of chaotisation are studied in this paper. The best variant is a permanent fiber deformation/chaotisation of fibers using integrated heating/cooling and stretching. The tested CFPFHEs (Chaotised Flexible Polymeric Fiber Heat Exchangers) had an overall heat transfer area of 1 m2, and its length was approximately 700 mm. It achieved a water/air overall heat transfer coefficient of 100 W/m2 K with an outside air flow of 2 m/s.
English abstract
Flexible polymeric hollow fibers are used as heat transfer elements. A potted bundle of several hundred such fibers can be used as a heat exchanger in different ways. The simplest application is a submerged bundle. The fibers studied in this paper have outside diameters below 0.8 mm. Such very small-diameter polymer fibers significantly facilitate heat transfer. However, these potted sets of fibers must be designed to guarantee that all fibers are in direct contact with the surrounding stream of fluid. It is possible to use textile technologies to keep fibers strictly parallel and separated. However, a parallel arrangement can be expensive and is not flexible. A low-cost variant utilizes bundle chaotisation, which means that each fiber has a unique shape. The consequence is that their mutual mechanical contacts are point-wise. Several methods of chaotisation are studied in this paper. The best variant is a permanent fiber deformation/chaotisation of fibers using integrated heating/cooling and stretching. The tested CFPFHEs (Chaotised Flexible Polymeric Fiber Heat Exchangers) had an overall heat transfer area of 1 m2, and its length was approximately 700 mm. It achieved a water/air overall heat transfer coefficient of 100 W/m2 K with an outside air flow of 2 m/s.
Keywords in English
Plastic heat exchanger; Hollow fiber; Chaotic structure; Heat transfer coefficient
Released
25.02.2017
Publisher
Elsevier Limited
ISSN
1359-4311
Number
113
Pages from–to
632–638
Pages count
7
BIBTEX
@article{BUT131820,
author="Miroslav {Raudenský} and Ilja {Astrouski} and Mirko {Dohnal},
title="Intensification of heat transfer of polymeric hollow fiber heat exchangers by chaotisation",
year="2017",
number="113",
month="February",
pages="632--638",
publisher="Elsevier Limited",
issn="1359-4311"
}