Microchannel Condensation Heat Transfer
Lead Research Organisation:
Queen Mary University of London
Department Name: School of Engineering & Materials Scienc
Abstract
Around 50% of the electricity consumption of large food retailers in the UK is for cooling chilled and frozen food cabinets. Their total annual electrical energy consumption is almost 10 TWh. As early as 1994, 10% of floor space in the UK was serviced by air-conditioning. The figure is now more than 25% for buildings constructed during the past 10 years. The condenser is a key component of vapour compression refrigeration and air conditioning plant. Wide implementation of well-designed microchannel condensers would lead to a reduction of around 20% in power requirement. In the UK this represents a significant decrease in fossil fuel consumption and carbon dioxide emissions. Improved designs would also be significantly smaller, have smaller fluid inventories and possibly lower capital cost. Established design methods for larger channels fail for channel dimensions around 1 mm owing to surface tension effects. A wholly-theoretical model, valid for condensation of any fluid in microchannels, has been developed at Queen Mary (QM) under research programmes supported by EPSRC. Available experimental data are insufficient in number and reliability, and do not cover a sufficiently wide range of fluid properties, to validate and extend the theory. In most investigations vapour-side, heat-transfer coefficients are deduced from overall coolant-to-vapour measurements and are consequently of relatively low accuracy. Four correlations representing measurements for R134a agree to within about 30% for this fluid but differ by a factor of around 4 for ammonia. Existing correlations evidently do not correctly capture fluid property effects.The QM theoretical model has no recourse to experimental data. It includes transverse flow due to surface tension as well as shear stress and gravity effects and has been used to generate results for various fluids, channel shapes and dimensions, vapour flow rates and channel inclinations. The predictions fall within the ranges of the results given by the correlations. Theoretical results for seven fluids have been widely disseminated in conference proceedings (9 papers) and in archival journals (5 papers). A simple algebraic relation between two dimensionless parameters has recently been developed which predicts, very accurately, numerically-obtained results for the surface tension dominated flow regime for different channel cross section, fluids, vapour flow rates and temperature differences. Similar simplified results will be obtained for the flow regimes upstream and downstream of the surface tension dominated region so as to provide readily usable formulae for complete condenser design.An innovative technique will be used to measure local temperatures and heat fluxes in microchannels. A new apparatus has been designed in which parallel microchannels (1.5 mm x 1.0 mm) pass through the centre of a copper block (30 mm x 40 mm x 500 mm long) in which temperatures are very accurately measured (to within 0.05 K) at 98 precisely-known (to within 0.3 mm) locations. The observations will be used in inverse solutions of the conduction equation to determine local vapour-side surface temperatures (to within 0.1 K) and heat fluxes (to within 5%). Flow visualization studies will also be performed in which the upper part of the test block is replaced by glass so that the flow in the channels may be observed using high-speed photography.Two fluids (steam and FC72) with widely different thermophysical properties, notably surface tension, will be used. These data will provide a stringent test of the present theory and facilitate its extension to cover other flow regimes. The final model should be valid for any fluid, channel geometry, vapour flow rate and vapour-to-wall temperature difference. This will facilitate design and optimisation of a new generation of large scale refrigeration and air conditioning equipment.
People |
ORCID iD |
John Rose (Principal Investigator) | |
Hua Sheng Wang (Co-Investigator) |
Publications
Liu N
(2013)
Heat transfer and pressure drop during condensation of R152a in circular and square microchannels
in Experimental Thermal and Fluid Science
Sheng Wang H
(2017)
Condensation in Microchannels: Detailed Comparisons of Annular Laminar Flow Theory With Measurements
in Journal of Heat Transfer
Sun J
(2012)
Multi-scale study of liquid flow in micro/nanochannels: effects of surface wettability and topology
in Microfluidics and Nanofluidics
Sun J
(2009)
Scale effect on flow and thermal boundaries in micro-/nano-channel flow using molecular dynamics-continuum hybrid simulation method
in International Journal for Numerical Methods in Engineering
Sun J
(2013)
Dependence of nanoconfined liquid behavior on boundary and bulk factors.
in Physical review. E, Statistical, nonlinear, and soft matter physics
Sun J
(2013)
Dependence between velocity slip and temperature jump in shear flows.
in The Journal of chemical physics
Wang H
(2011)
Theory of heat transfer during condensation in microchannels
in International Journal of Heat and Mass Transfer
Wang H
(2013)
Heat Transfer and Pressure Drop During Laminar Annular Flow Condensation in Micro-Channels
in Experimental Heat Transfer
Wang H
(2013)
Pressure Drop During Condensation in Microchannels
in Journal of Heat Transfer
Wang HS
(2012)
Pressure drop during condensation in microchannels
Description | A novel measurement method based on inverse heat conduction has been developed to accurately measure heat transfer along the flow direction in microchannels. Experimental data of heat transfer and pressure drop have been obtained for the use of design. A simple dimensionless algebraic equation has first been derived, valid for any fluid, channel geometry and very convenient for use in design and optimization of microchannel condensers. |
Exploitation Route | The research findings have been published in national/international conferences and journals and are recently used for R&D of heat exchanger products by our industry partners. |
Sectors | Aerospace Defence and Marine Education Energy Environment Manufacturing including Industrial Biotechology Transport |
Description | The research findings have been recently used for R&D of heat exchanger products by our industry partners. |
Sector | Aerospace, Defence and Marine,Agriculture, Food and Drink,Energy,Environment,Manufacturing, including Industrial Biotechology,Transport |
Impact Types | Economic |