Sage Journals: Discover world-class research

Abstract

Liquid-to-air membrane energy exchanger is a novel membrane base energy exchanger, which allows both heat and moisture transfer between air and a salt solution. The heat and mass transfer performance of a single one is significantly dependent on two dimensionless parameters: number of heat transfer units and the ratio of heat capacity rates between solution flow and air flow (Cr*). The performance of liquid-to-air membrane energy exchanger under high Cr* (i.e. Cr* ≥ 1) has been comprehensively investigated experimentally and numerically in previous research. In this study, the effectiveness of a small-scale liquid-to-air membrane energy exchanger under low Cr* conditions (i.e. Cr* < 1) is experimentally tested. Good agreement between the experimental and numerical results is achieved under low Cr* cases.

Practical application : The ideal energy exchanger is one that can transfer both heat and moisture because during hot and humid conditions such an exchanger is capable of transferring up to four times as much energy as an exchanger that can transfer sensible heat only. It is beneficial if the exchanger can transfer heat and moisture also between remote supply and exhaust airstreams, as this may minimize the ducting required and reduces contaminant transfer from one airstream to the other. This is very important for applications such as hospitals, laboratories, and manufacturing facilities, where slight cross contamination can cause serious health effects.

Keywords

Energy exchanger performance effectiveness liquid desiccant air-conditioning ventilation liquid-to-air membrane

Get full access to this article

View all access options for this article.

References

Nguyen

Kim

Shin

. Experimental study of sensible heat recovery of heat pump during heating and ventilation. Int J Refrig 2005; 28: 242–252.

Zhang

. Energy performance of independent air dehumidification systems with energy recovery measures. Energy 2006; 31: 1228–1242.

Zhang

Zhu

Deng

. Thermodynamic modelling of a novel air dehumidification system. Energy Build 2005; 37: 279–286.

Mats

Wilhelm

Matthias

. Membrane heat exchanger in HVAC energy recovery systems, systems energy analysis. Int J Refrig 2002; 25: 439–449.

Zhang

Niu

. Energy requirements for conditioning fresh air and the long-term savings with a membrane-based energy recovery ventilator in Hong Kong. Energy 2001; 26: 119–135.

Zhou

Wang

. Performance of energy recovery ventilator with various weathers and temperature set-points. Energy Build 2007; 39: 1202–1210.

Yau

. Analyses of heat recovery devices in the HVAC system in an operating theatre in the tropics. Build Serv Eng Res Technol 2010; 31/4: 341–355.

Zhang

Niu

. Effectiveness correlations for heat and moisture transfer processes in an enthalpy exchanger with membrane cores. J Heat Transfer 2002; 124: 922–929.

Zhang

Niu

. Performance comparisons of desiccant wheels for air dehumidification and enthalpy recovery. Appl Thermal Eng 2002; 22: 1347–1367.

10.

Yau

Ahmadzadehtalatapeh

. The empirical study of a four-row heat pipe heat exchanger to predict the year-round energy recovery in the tropics. Build Serv Eng Res Technol 2011; 32/4: 307–327.

11.

Ghadiri-Moghaddam

LePoudre

. Small-scale single-panel liquid-to-air membrane energy exchanger (LAMEE) test facility development, commissioning and evaluating the steady-state performance. Energy Build 2013; 66: 424–436.

12.

Ghadiri-Moghaddam

Abdel-Salam

. Comparison of experimental data and a model for heat and mass transfer performance of a liquid-to-air membrane energy exchanger (LAMEE) when used for air dehumidification and salt solution regeneration. Int J Heat Mass Transfer 2014; 68: 119–131.

13.

Davood

Ashkan

. Numerical model of a small-scale liquid-to-air membrane energy exchanger: parametric study of membrane resistance and air side convective heat transfer coefficient. Appl Thermal Eng 2013; 61: 245–258.

14.

Namvar

Pyra

. Transient characteristics of a liquid-to-air membrane energy exchanger (LAMEE) experimental data with correlations. Int J Heat Mass Transfer 2012; 55: 6682–6694.

15.

Namvar

Simonson

. Transient heat and moisture transfer characteristics of a liquid-to-air membrane energy exchanger (LAMEE) model verification and extrapolation. Int J Heat Mass Transfer 2013; 66: 757–771.

16.

Abdel-Salam

Simonson

. Performance analysis of a membrane liquid desiccant air-conditioning system. Energy Build 2013; 62: 559–569.

17.

Ghadiri Moghaddam D, Philip L and Besant RW. Evaluating the steady-state performance of a smallscale single-panel liquid-to-air membrane energy exchanger (LAMEE) under summer AHRI test condition. In: Proceedings of CLIMA 2013: 11th REHVA World Congress and 8th international conference on IAQVEC. Prague, 6--19 June 2013.

18.

Ghadiri-Moghaddam

Namvar

. Analytical model based performance evaluation, sizing and coupling flow optimization of liquid desiccant run-around membrane energy exchanger systems. Energy Build 2013; 62: 248–257.

19.

Hemingson HB. The impacts of outdoor air conditions and non-uniform exchanger channels on a run-around membrane energy exchanger. M.Sc. Thesis, University of Saskatchewan, Saskatoon, 2010.

20.

Zhang

Niu

. Membrane-based enthalpy exchanger: material consideration and clarification of moisture resistance. J Membr Sci 2001; 189: 179–191.

21.

Zhang

. An analytical solution to heat and mass transfer in hollow fiber membrane contactors for liquid desiccant air dehumidification. ASME J Heat Transfer 2011; 133: 1–8.

22.

Welty

Wicks

Rorrer

. Fundamentals of momentum, heat, and mass transfer, New York: John Wiley & Sons Inc, 2001.

23.

Zhang

Huang

Chi

. Conjugate heat and mass transfer in a hollow fiber membrane module for liquid desiccant air dehumidification: a free surface model approach. Int J Heat Mass Transfer 2012; 55: 3789–3799.

24.

Morrison SN, Morrison GL and Behnia M. Heat and mass transfer in air to air enthalpy heat exchangers In: Proceedings, 6th international conference on heat transfer, fluid mechanics and thermodynamics. Matsushima, Miyagi, Japan, 17--21 April 2005.

25.

ANSI/AHRI Standard 1060 (I-P): Performance rating of air-to-air heat exchangers for energy recovery ventilation equipment, 2011.

Performance investigation of liquid-to-air membrane energy exchanger under low solution/air heat capacity rates ratio conditions

Abstract

Keywords

Get full access to this article

References