Transient conjugated heat transfer in microchannels: Integral transforms with single domain formulation

• Published in: International journal of thermal sciences Vol. 88; pp. 248 - 257
• Main Authors: Knupp, Diego C., Cotta, Renato M., Naveira-Cotta, Carolina P., Kakaç, Sadik
• Format: Journal Article
• Language: English
• Published: Elsevier Masson SAS 01.02.2015
• Subjects: Channels; Conjugated problem; GITT; Heat transfer; Integral transforms; Integrals; Mathematical models; Micro-heat exchanger; Microchannel; Microchannels; Thermal resistance; Transforms; Transient convection; Walls; Transient convection; Integral transforms; Conjugated problem; Micro-heat exchanger; GITT; Microchannel
• ISSN: 1290-0729; 1778-4166
• DOI: 10.1016/j.ijthermalsci.2014.04.017

The transient behaviour of conjugated heat transfer in laminar microchannel flow is investigated, taking into account the axial diffusion effects, which are often of relevance in microchannels, and including pre-heating or pre-cooling of the region upstream of the heat exchange section. The solution methodology is based on the Generalized Integral Transform Technique (GITT), as applied to a single domain formulation proposed for modelling the heat transfer phenomena at both the fluid stream and the channel wall regions. By making use of coefficients represented as space dependent functions with abrupt transitions occurring at the fluid–wall interfaces, the mathematical model carries the information concerning the transition of the two domains, unifying the model into a single domain formulation with variable coefficients. The proposed approach is illustrated for microchannels with polymeric walls of different thicknesses. The accuracy of approximate internal wall temperature estimates deduced from measurements of the external wall temperatures, accounting only for the thermal resistance across the wall thickness, is also analyzed. •Transient behaviour of conjugated heat transfer in laminar microchannel flow is investigated.•The analysis includes pre-heating or pre-cooling of the region upstream of the heat exchange section.•A hybrid numerical-analytical solution based on integral transforms is advanced to tackle the problem.•The present solution is critically compared to a finite element solution from a commercial code with excellent agreement.•The accuracy of approximate internal wall temperatures obtained from measurements of the external temperatures is analyzed.