Simultaneous heat and water recovery from flue gas by membrane condensation: Experimental investigation

Applied Thermal Engineering

Volumn 113, Issue , 2017, Pages 843-850

  Zhao, Shuaifei ^a,b   Yan, Shuiping ^c   Wang, David K ^d   Wei, Yibin ^a   Qi, Hong ^e   Wu, Tao ^f   Feron, Paul H M ^b  

^a MACQUARIE UNIVERSITY   (Australia)

^b CSIRO   (Australia)

^c HUAZHONG AGRICULTURAL UNIVERSITY   (China)

^d UNIVERSITY OF QUEENSLAND   (Australia)

^e NANJING TECH UNIVERSITY   (China)

^f ZHEJIANG UNIVERSITY OF TECHNOLOGY   (China)

Author keywords

Flue gas; Heat recovery; Heat transfer; Low grade heat; Membrane condenser; Water recovery

Indexed keywords

CERAMIC MEMBRANES; CONDENSATION; COOLANTS; EFFICIENCY; FLOW OF GASES; FLOW OF WATER; FLUE GASES; FLUES; GASES; HEAT TRANSFER; HEAT TRANSFER COEFFICIENTS; MEMBRANE TECHNOLOGY; MEMBRANES; RECOVERY; WASTE HEAT; WASTE HEAT UTILIZATION;

EXPERIMENTAL INVESTIGATIONS; HEAT TRANSFER EFFICIENCY; LOW GRADE HEAT; MASS AND HEAT TRANSFERS; OPERATIONAL PARAMETERS; OVERALL HEAT TRANSFER COEFFICIENT; TUBULAR CERAMIC MEMBRANES; WATER RECOVERY;

HEAT EXCHANGERS;

EID: 84996489193     PISSN: 13594311     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.applthermaleng.2016.11.101     Document Type: Article

References (39)

1. [1] Al-Mousawi, F.N., Al-Dadah, R., Mahmoud, S., Low grade heat driven adsorption system for cooling and power generation using advanced adsorbent materials. Energy Convers. Manage. 126 (2016), 373–384.
2. [2] Maalouf, S., Ksayer, E. Boulawz, Clodic, D., Investigation of direct contact condensation for wet flue-gas waste heat recovery using organic Rankine cycle. Energy Convers. Manage. 107 (2016), 96–102.
3. [3] Terhan, M., Comakli, K., Design and economic analysis of a flue gas condenser to recover latent heat from exhaust flue gas. Appl. Therm. Eng. 100 (2016), 1007–1015.
4. [4] Han, X., Yan, J., Karellas, S., Liu, M., Kakaras, E., Xiao, F., Water extraction from high moisture lignite by means of efficient integration of waste heat and water recovery technologies with flue gas pre-drying system. Appl. Therm. Eng. 110 (2017), 442–456.
5. [5] Xu, G., Huang, S., Yang, Y., Wu, Y., Zhang, K., Xu, C., Techno-economic analysis and optimization of the heat recovery of utility boiler flue gas. Appl. Energy 112 (2013), 907–917.
6. [6] Judd, S., Jefferson, B., Membranes for Industrial Wastewater Recovery and Re-Use. 2003, Elsevier.
7. [7] Water Capture. < http://www.watercapture.eu/>.
8. [8] Wang, D., Transport Membrane Condenser for Water and Energy Recovery mFrom Power Plant Flue Gas. Final technical report, 2012, Gas Technology Institute.
9. [9] BCS, Incorporated, Waste Heat Recovery: Technology and Opportunities in US Industry, U.S. Department of Energy, 2008.
10. [10] Wang, D., Bao, A., Kunc, W., Liss, W., Coal power plant flue gas waste heat and water recovery. Appl. Energy 91 (2012), 341–348.
11. [11] Tchanche, B.F., Lambrinos, G., Frangoudakis, A., Papadakis, G., Low-grade heat conversion into power using organic Rankine cycles - a review of various applications. Renew. Sustain. Energy Rev. 15 (2011), 3963–3979.
12. [12] Zhang, J., Zhou, Y., Li, Y., Hou, G., Fang, F., Generalized predictive control applied in waste heat recovery power plants. Appl. Energy 102 (2013), 320–326.
13. [13] Westerlund, L., Hermansson, R., Fagerström, J., Flue gas purification and heat recovery: a biomass fired boiler supplied with an open absorption system. Appl. Energy 96 (2012), 444–450.
14. [14] Li, Y., Yan, M., Zhang, L., Chen, G., Cui, L., Song, Z., Chang, J., Ma, C., Method of flash evaporation and condensation - heat pump for deep cooling of coal-fired power plant flue gas: latent heat and water recovery. Appl. Energy 172 (2016), 107–117.
15. [15] Messerer, A., Schmatloch, V., Pöschl, U., Niessner, R., Combined particle emission reduction and heat recovery from combustion exhaust - a novel approach for small wood-fired appliances. Biomass Bioenergy 31 (2007), 512–521.
16. [16] Gröhn, A., Suonmaa, V., Auvinen, A., Lehtinen, K.E.J., Jokiniemi, J., Reduction of fine particle emissions from wood combustion with optimized condensing heat exchangers. Environ. Sci. Technol. 43 (2009), 6269–6274.
17. [17] Hu, H.W., Tang, G.H., Niu, D., Wettability modified nanoporous ceramic membrane for simultaneous residual heat and condensate recovery. Sci. Rep., 6, 2016, 27274.
18. [18] Bao, A., Wang, D., Lin, C.-X., Nanoporous membrane tube condensing heat transfer enhancement study. Int. J. Heat Mass Transf. 84 (2015), 456–462.
19. [19] Yue, M., Zhao, S., Feron, P.H.M., Qi, H., Multichannel tubular ceramic membrane for water and heat recovery from waste gas streams. Ind. Eng. Chem. Res. 55 (2016), 2615–2622.
20. [20] Macedonio, F., Brunetti, A., Barbieri, G., Drioli, E., Membrane condenser as a new technology for water recovery from humidified “waste” gaseous streams. Ind. Eng. Chem. Res. 52 (2012), 1160–1167.
21. [21] Brunetti, A., Santoro, S., Macedonio, F., Figoli, A., Drioli, E., Barbieri, G., Waste gaseous streams: from environmental issue to source of water by using membrane condensers. CLEAN - Soil Air Water 42 (2014), 1145–1153.
22. [22] Drioli, E., Santoro, S., Simone, S., Barbieri, G., Brunetti, A., Macedonio, F., Figoli, A., ECTFE membrane preparation for recovery of humidified gas streams using membrane condenser. React. Funct. Polym. 79 (2014), 1–7.
23. [23] Chen, H., Zhou, Y., Cao, S., Li, X., Su, X., An, L., Gao, D., Heat exchange and water recovery experiments of flue gas with using nanoporous ceramic membranes. Appl. Therm. Eng. 110 (2017), 686–694.
24. [24] DeBusk, M.M., Bischoff, B., Hunter, J., Klett, J., Nafziger, E., Daw, S., Understanding the effect of dynamic feed conditions on water recovery from IC engine exhaust by capillary condensation with inorganic membranes. Dogan, F., Tritt, T.M., Sekino, T., Katoh, Y., Pyzik, A.J., Belharouak, l., Boccaccini, A.R., Marra, J., Lin, H.-T., (eds.) Ceramics for Environmental and Energy Applications II, 2014, John Wiley & Sons Inc, 141–152.
25. [25] Yan, S., Zhao, S., Wardhaugh, L.T., Feron, P.H.M., Innovative use of membrane contactor as condenser for heat recovery in carbon capture. Environ. Sci. Technol. 49:4 (2015), 2532–2540.
26. [26] Macedonio, F., Cersosimo, M., Brunetti, A., Barbieri, G., Drioli, E., Water recovery from humidified waste gas streams: quality control using membrane condenser technology. Chem. Eng. Process. 86 (2014), 196–203.
27. [27] Wang, T., Yue, M., Qi, H., Feron, P.H.M., Zhao, S., Transport membrane condenser for water and heat recovery from gaseous streams: performance evaluation. J. Membr. Sci. 484 (2015), 10–17.
28. [28] Sekulic-Kuzmanovic, J., Mesoporous and microporous titania membranes. PhD thesis, 2004, University of Twente, Enschede.
29. 3 with narrow size distribution. Ceram. Int. 39 (2013), 2463–2471.
30. [30] Jakobs, E., Koros, W.J., Ceramic membrane characterization via the bubble point technique. J. Membr. Sci. 124 (1997), 149–159.
31. [31] Feng, J., Fan, Y., Qi, H., Xu, N., Co-sintering synthesis of tubular bilayer α-alumina membrane. J. Membr. Sci. 288 (2007), 20–27.
32. [32] Zhao, S., Feron, P.H.M., Xie, Z., Zhang, J., Hoang, M., Condensation studies in membrane evaporation and sweeping gas membrane distillation. J. Membr. Sci. 462 (2014), 9–16.
33. [33] Zhao, S., Cao, C., Wardhaugh, L., Feron, P.H.M., Membrane evaporation of amine solution for energy saving in post-combustion carbon capture: performance evaluation. J. Membr. Sci. 473 (2015), 274–282.
34. [34] Khayet, M., Godino, M.P., Mengual, J.I., Thermal boundary layers in sweeping gas membrane distillation processes. AIChE J. 48 (2002), 1488–1497.
35. [35] Khayet, M., Godino, P., Mengual, J.I., Theory and experiments on sweeping gas membrane distillation. J. Membr. Sci. 165 (2000), 261–272.
36. [36] Hwang, K., Song, C.H., Saito, K., Kawai, S., Experimental study on titanium heat exchanger used in a gas fired water heater for latent heat recovery. Appl. Therm. Eng. 30 (2010), 2730–2737.
37. [37] Jeong, K., Kessen, M.J., Bilirgen, H., Levy, E.K., Analytical modeling of water condensation in condensing heat exchanger. Int. J. Heat Mass Transf. 53 (2010), 2361–2368.
38. [38] Xie, Z., Duong, T., Hoang, M., Nguyen, C., Bolto, B., Ammonia removal by sweep gas membrane distillation. Water Res. 43 (2009), 1693–1699.
39. [39] Zhao, S., Wardhaugh, L., Zhang, J., Feron, P.H.M., Condensation, re-evaporation and associated heat transfer in membrane evaporation and sweeping gas membrane distillation. J. Membr. Sci. 475 (2015), 445–454.