Potential Life Cycle Carbon Savings for Immersion Freezing of Water by Power Ultrasound

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• 作者：Zhongyue Xu ; Da-Wen Sun ; Zhiwei Zhu
• 关键词：Immersion freezing ; Ultrasound ; assisted freezing ; Freezing unit ; Carbon footprint
• 刊名：Food and Bioprocess Technology
• 出版年：2016
• 出版时间：January 2016
• 年：2016
• 卷：9
• 期：1
• 页码：69-80
• 全文大小：499 KB
• 参考文献：AEA Technology (2004). Emissions and projections of HFCs, PFCs and SF6 for the UK and constituent countries. Report No AEAT/ED50090/R01 prepared for the UK Department for Environment, Food and Rural Affairs, London, UK.
  Alizadeh, E., Chapleau, N., de Lamballerie, M., & Le-Bail, A. (2007). Effect of different freezing processes on the microstructure of Atlantic salmon (Salmo salar) fillets. Innovative Food Science & Emerging Technologies, 8(4), 493–499.CrossRef
  Anese, M., Manzocco, L., Panozzo, A., Beraldo, P., Foschia, M., & Nicoli, M. C. (2012). Effect of radiofrequency assisted freezing on meat microstructure and quality. Food Research International, 46(1), 50–54.CrossRef
  Bahman, A., Rosario, L., & Rahman, M. M. (2012). Analysis of energy savings in a supermarket refrigeration/HVAC system. Applied Energy, 98, 11–21.CrossRef
  Bermúdez-Aguirre, D., & Barbosa-Cánovas, G. V. (2008). Study of butter fat content in milk on the inactivation of Listeria innocua ATCC 51742 by thermo-sonication. Innovative Food Science & Emerging Technologies, 9(2), 176–185.CrossRef
  BSI (2011). Publicly Available Specification (PAS 2050: 2011): Specification for the assessment of the life cycle greenhouse gas emissions of goods and services. British Standards Institution (BSI), London.
  Carcione, J. M., Campanella, O. H., & Santos, J. E. (2007). A poroelastic model for wave propagation in partially frozen orange juice. Journal of Food Engineering, 80(1), 11–17.CrossRef
  Cellura, M., Longo, S., & Mistretta, M. (2012). Life cycle assessment (LCA) of protected crops: an Italian case study. Journal of Cleaner Production, 28, 56–62.CrossRef
  Chakraboty, P. K., & Pillai, S. A. (1977). Application of cryogenics in fish processing. Indian Journal of Cryogen, 2(4), 260–6.
  Chemat, F., Zill-e, H., & Khan, M. K. (2011). Applications of ultrasound in food technology: processing, preservation and extraction. Ultrasonics Sonochemistry, 18(4), 813–835.CrossRef
  Chourot, J., Macchi, H., Fournaison, L., & Guilpart, J. (2003). Technical and economical model for the freezing cost comparison of immersion, cryomechanical and air blast freezing processes. Energy Conversion and Management, 44(4), 559–571.CrossRef
  Chow, R., Blindt, R., Chivers, R., & Povey, M. (2005). A study on the primary and secondary nucleation of ice by power ultrasound. Ultrasonics, 43(4), 227–230.CrossRef
  Cui, Z.-W., Sun, L.-J., Chen, W., Sun, D.-W. (2008). Preparation of dry honey by microwave-vacuum drying. Journal of Food Engineering, 84(4), 582–590.
  De Monte, M., Padoano, E., & Pozzetto, D. (2005). Alternative coffee packaging: an analysis from a life cycle point of view. Journal of Food Engineering, 66(4), 405–411.CrossRef
  DECC (2011). Development of the GHG refrigeration and air conditioning model: final report. Prepared for the Department of Energy and Climate Change (DECC) By ICF International.
  DEFRA (2012). 2012 Guidelines to Defra / DECC’s GHG Conversion Factors for Company Reporting: Methodology Paper for Emission Factors. https://​www.​gov.​uk/​government/​uploads/​system/​uploads/​attachment_​data/​file/​69568/​pb13792-emission-factor-methodology-paper-120706.​pdf . Accessed May 2015.
  Delgado, A., & Sun, D.-W. (2001). Heat and mass transfer models for predicting freezing processes—a review. Journal of Food Engineering, 47(3), 157–74.CrossRef
  Delgado, A.E., Sun, D.-W. (2002). Desorption isotherms and glass transition temperature for chicken meat. Journal of Food Engineering, 55(1), 1–8.
  Delgado, A. E., Zheng, L., & Sun, D.-W. (2008). Influence of ultrasound on freezing rate of immersion-frozen apples. Food and Bioprocess Technology, 2(3), 263–270.CrossRef
  Desmond, E. M., Kenny, T. A., Ward, P., Sun, D.-W. (2000). Effect of rapid and conventional cooling methods on the quality of cooked ham joints. Meat science, 56(3), 271–277.
  Eh, A. L., & Teoh, S. G. (2012). Novel modified ultrasonication technique for the extraction of lycopene from tomatoes. Ultrasonics Sonochemistry, 19(1), 151–159.CrossRef
  Elmehdi, H., Page, J., & Scanlon, M. (2003). Using ultrasound to investigate the cellular structure of bread crumb. Journal of Cereal Science, 38(1), 33–42.CrossRef
  EPA (2008). Climate leaders: greenhouse gas inventory protocol core module guidance. Direct HFC and PFC emissions from use of refrigeration and air conditioning equipment. http://​www.​epa.​gov/​climateleadershi​p/​documents/​resources/​mfgrfg.​pdf . Accessed May 2015.
  EPD (2012). BH Ecologique bottle. http://​www.​environdec.​com/​en/​Detail/​?​Epd=​8120 . Accessed May 2015.
  Foster, C., Green, K., Bleda, M., Dewick, P., Evans, B., Flynn, A., & Mylan, J. (2006). Environmental impacts of food production and consumption: a report to the department for environment, food and rural affairs. Defra: Manchester Business School.
  Frischknecht, R., Althaus, H.-J., Bauer, C., Doka, G., Heck, T., Jungbluth, N., Kellenberger, D., & Nemecek, T. (2007). The environmental relevance of capital goods in life cycle assessments of products and services. International Journal of Life Cycle Assessment, 12(1), 7–17.
  Fuchigami, M., & Kato, N. (1998). High‐pressure‐freezing effects on textural quality of Chinese cabbage. Journal of Food Science, 63(1), 122–125.CrossRef
  Garnett, T. (2007). Food refrigeration: what is the contribution to greenhouse gas emissions and how might emissions be reduced. A working paper produced as part of the Food Climate Research Network. Centre for Environmental Strategy, University of Surrey, UK. http://​fcrn.​org.​uk/​sites/​default/​files/​FCRN%20​refrigeration%20​paper%20​final.​pdf . Accessed May 2015.
  Haiying, W., Shaozhi, Z., & Guangming, C. (2007). Experimental study on the freezing characteristics of four kinds of vegetables. LWT--Food Science and Technology, 40(6), 1112–1116.CrossRef
  Hesson, J. R. (2013). Fundamentals of ultrasonic cleaning. http://​hessonic.​com/​fundamentals-of-ultrasonic-cleaning . Accessed May 2015.
  Hu, S.-Q., Liu, G., Li, L., Li, Z.-X., & Hou, Y. (2013a). An improvement in the immersion freezing process for frozen dough via ultrasound irradiation. Journal of Food Engineering, 114(1), 22–28.
  Hu, F., Sun, D.-W., Gao,W., Zhang, Z., Zeng, X., Z. Han. (2013b). Effects of pre-existing bubbles on ice nucleation and crystallization during ultrasound assisted freezing of water and sucrose solution. Innovative Food Science and Emerging Technologies, 20, 161–166.
  IPCC (2006). Guidelines for National Greenhouse Inventories. http://​www.​ipcc-nggip.​iges.​or.​jp/​public/​2006gl/​vol5.​html . Accessed May 2015.
  IPCC (2007) Climate Change 2007: Synthesis Report. Contribution of Working Groups I, II and III to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. IPCC, Geneva, Switzerland. http://​www.​ipcc.​ch/​pdf/​assessment-report/​ar4/​syr/​ar4_​syr.​pdf . Accessed May 2015.
  Islam, M. N., Zhang, M., Adhikari, B., Cheng, X. F., & Xu, B. G. (2014). The effect of ultrasound-assisted immersion freezing on selected physicochemical properties of mushrooms. International Journal of Refrigeration-Revue Internationale Du Froid, 42, 121–133.CrossRef
  ISO 14040. (2006). Environmental management-life cycle assessment-principles and framework. Geneva: International Organization for Standardization.
  ISO 14044. (2006). Environmental management-life cycle assessment-requirements and guidelines. Geneva: International Organization for Standardization.
  ISO 14067. (2011). Carbon footprint of products—requirements and guidelines for quantification and communication. Geneva: International Organization for Standardization.
  James, S. J., & James, C. (2010). The food cold-chain and climate change. Food Research International, 43(7), 1944–1956.CrossRef
  Khadatkar, R. M., Kumar, S., & Pattanayak, S. C. (2004). Cryofreezing and cryofreezer. Cryogenics, 44(9), 661–678.CrossRef
  Kiani, H., & Sun, D.-W. (2011). Water crystallization and its importance to freezing of foods: a review. Trends in Food Science & Technology, 22(8), 407–426.CrossRef
  Kiani, H., Zhang, Z., Delgado, A., & Sun, D.-W. (2011). Ultrasound assisted nucleation of some liquid and solid model foods during freezing. Food Research International, 44(9), 2915–2921.CrossRef
  Kiani, H., Sun, D.-W., Delgado, A., & Zhang, Z. (2012a). Investigation of the effect of power ultrasound on the nucleation of water during freezing of agar gel samples in tubing vials. Ultrasonics Sonochemistry, 19(3), 576–581.CrossRef
  Kiani, H., Sun, D.-W., & Zhang, Z. (2012b). The effect of ultrasound irradiation on the convective heat transfer rate during immersion cooling of a stationary sphere. Ultrasonics Sonochemistry, 19(6), 1238–1245.CrossRef
  Kiani, H., Zhang, Z., Sun, D.-W. (2013a). Effect of ultrasound irradiation on ice crystal size distribution in frozen agar gel samples. Innovative Food Science and Emerging Technologies, 18, 126–131.
  Kiani, H., Sun, D.-W., & Zhang, Z. (2013b). Effects of processing parameters on the convective heat transfer rate during ultrasound assisted low temperature immersion treatment of a stationary sphere. Journal of Food Engineering, 115(3) 384–390.
  Kiani, H., Zhang, Z., Sun, D.-W. (2015). Experimental analysis and modeling of ultrasound assisted freezing of potato spheres. Ultrasonics Sonochemistry, 26, 321–331.
  Lee, S., Pyrak-Nolte, L. J., Cornillon, P., & Campanella, O. (2004). Characterisation of frozen orange juice by ultrasound and wavelet analysis. Journal of the Science of Food and Agriculture, 84(5), 405–410.CrossRef
  Legay, M., Gondrexon, N., Le Person, S., Boldo, P., & Bontemps, A. (2011). Enhancement of heat transfer by ultrasound: review and recent advances. International Journal of Chemical Engineering, 2011, 1–17.CrossRef
  Li, B., & Sun, D.-W. (2002). Effect of power ultrasound on freezing rate during immersion freezing of potatoes. Journal of Food Engineering, 55(3), 277–282.CrossRef
  Loretz, M., Stephan, R., & Zweifel, C. (2010). Antimicrobial activity of decontamination treatments for poultry carcasses: a literature survey. Food Control, 21(6), 791–804.CrossRef
  Masanet, E., Worrell, E., Graus, W. and Galitsky, C. (2008). Energy efficiency improvement and cost saving opportunities for the fruit and vegetable processing industry.An Energy Star Guide for Energy and Plant Managers. Lawrence Berkeley National Laboratory. https://​escholarship.​org/​uc/​item/​8h25n5pr#page-1 . Accessed May 2015.
  Nakagawa, K., Hottot, A., Vessot, S., & Andrieu, J. (2006). Influence of controlled nucleation by ultrasounds on ice morphology of frozen formulations for pharmaceutical proteins freeze-drying. Chemical Engineering and Processing: Process Intensification, 45(9), 783–791.CrossRef
  NDRC (National Development and Reform Commission) (2012). 2012 Baseline emission factors for regional power grids in China. http://​cdm.​ccchina.​gov.​cn/​WebSite/​CDM/​UpFile/​File2975.​pdf . Accessed May 2015.
  Ngapo, T., Babare, I., Reynolds, J., & Mawson, R. (1999). Freezing rate and frozen storage effects on the ultrastructure of samples of pork. Meat Science, 53(3), 159–168.CrossRef
  O’Connell, S., & Stutz, M. (2010). Product carbon footprint (PCF) assessment of Dell laptop—results and recommendations. http://​ieeexplore.​ieee.​org/​xpl/​login.​jsp?​tp=​&​arnumber=​5507731&​url=​http%3A%2F%2Fieeexplore.​ieee.​org%2Fxpls%2Fabs_​all.​jsp%3Farnumber%3D5507731 . Accessed May 2015.
  Ortiz, I. M. (2006). Life cycle assessment as a tool for green chemistry: application to different advanced oxidation processes for wastewater treatment. Universitat Autònoma de Barcelona.
  Pandey, D., Agrawal, M., & Pandey, J. S. (2011). Carbon footprint: current methods of estimation. Environmental Monitoring and Assessment, 178(1–4), 135–160.CrossRef
  Pant, R., Köhler, A., De Beaufort, A., Braune, A., Frankl, P., Hauschild, M., Klöpffer, W., Kreissig, J., Linfors, L., & Masoni, P. (2008). Standardisation efforts to measure greenhouse gases and ‘carbon footprinting’for products. International Journal of Life Cycle Assessment, 13(2), 87–88.CrossRef
  Pelletier, N., & Tyedmers, P. (2010). Life cycle assessment of frozen tilapia fillets from Indonesian lake-based and pond-based intensive aquaculture systems. Journal of Industrial Ecology, 14(3), 467–481.CrossRef
  Petzold, G., & Aguilera, J. M. (2009). Ice morphology: fundamentals and technological applications in foods. Food Biophysics, 4(4), 378–396.CrossRef
  Raso, J., Mañas, P., Pagán, R., & Sala, F. J. (1999). Influence of different factors on the output power transferred into medium by ultrasound. Ultrasonics Sonochemistry, 5(4), 157–162.CrossRef
  Reap, J., Roman, F., Duncan, S., & Bras, B. (2008). A survey of unresolved problems in life cycle assessment. International Journal of Life Cycle Assessment, 13(5), 374–388.CrossRef
  Rebitzer, G., Ekvall, T., Frischknecht, R., Hunkeler, D., Norris, G., Rydberg, T., Schmidt, W. P., Suh, S., Weidema, B. P., & Pennington, D. W. (2004). Life cycle assessment part 1: framework, goal and scope definition, inventory analysis, and applications. Environment International, 30(5), 701–720.CrossRef
  Rotz, C. A., Montes, F., & Chianese, D. S. (2010). The carbon footprint of dairy production systems through partial life cycle assessment. Journal of Dairy Science, 93(3), 1266–1282.CrossRef
  Roy, P., Nei, D., Orikasa, T., Xu, Q., Okadome, H., Nakamura, N., & Shiina, T. (2009). A review of life cycle assessment (LCA) on some food products. Journal of Food Engineering, 90(1), 1–10.CrossRef
  Salvadori, V. O., & Mascheroni, R. H. (2002). Analysis of impingement freezers performance. Journal of Food Engineering, 54(2), 133–140.CrossRef
  Schmidt Rivera, X. C., Espinoza Orias, N., & Azapagic, A. (2014). Life cycle environmental impacts of convenience food: comparison of ready and home-made meals. Journal of Cleaner Production, 73, 294–309.CrossRef
  Smith, N. A. S., Peppin, S. S. L., & Ramos, A. M. (2012). Generalized enthalpy model of a high-pressure shift freezing process. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, 468(2145), 2744–2766.CrossRef
  Stutz, M. (2010). Carbon footprint of a typical business laptop from Dell. http://​i.​dell.​com/​sites/​content/​corporate/​corp-comm/​en/​Documents/​dell-laptop-carbon-footprint-whitepaper.​pdf . Assessed May 2015.
  Sun, D.-W., Wang, L.J. (2000). Heat transfer characteristics of cooked meats using different cooling methods. International Journal of Refrigeration-revue Internationale du Froid, 23(7), 508–516.
  Sun, D.-W., & Li, B. (2003). Microstructural change of potato tissues frozen by ultrasound-assisted immersion freezing. Journal of Food Engineering, 57(4), 337–345.CrossRef
  Tassou, S. A., De-Lille, G., & Ge, Y. T. (2009). Food transport refrigeration—approaches to reduce energy consumption and environmental impacts of road transport. Applied Thermal Engineering, 29(8–9), 1467–1477.CrossRef
  Tassou, S. A., Lewis, J. S., Ge, Y. T., Hadawey, A., & Chaer, I. (2010). A review of emerging technologies for food refrigeration applications. Applied Thermal Engineering, 30(4), 263–276.CrossRef
  Vázquez-Rowe, I., Villanueva-Rey, P., Moreira, M. T., & Feijoo, G. (2013). The role of consumer purchase and post-purchase decision-making in sustainable seafood consumption. A Spanish case study using carbon footprinting. Food Policy, 41, 94–102.CrossRef
  Wang, L.J., Sun, D.-W. (2002a). Modelling vacuum cooling process of cooked meat - part 1: analysis of vacuum cooling system. International Journal of Refrigeration-Revue Internationale du Froid, 25(7), 854–861.
  Wang, L.J., Sun, D.-W.(2002b). Modelling vacuum cooling process of cooked meat - part 2: mass and heat transfer of cooked meat under vacuum pressure. International Journal of Refrigeration-Revue Internationale du Froid, 25(7), 862–871.
  Wang, L.J., Sun, D.-W. (2004). Effect of operating conditions of a vacuum cooler on cooling performance for large cooked meat joints. Journal of Food Engineering, 61(2), 231–240.
  Wang, C. H., & Lin, S. Y. (2010). The non-linear motion of bubbles with ultrasound. Acta Mechanica Sinica, 46(6), 1050–1059.
  Widehem, P., & Cochet, N. (2003). Pseudomonas syringae as an ice nucleator—application to freeze-concentration. Process Biochemistry, 39(4), 405–410.CrossRef
  Wiedmann, T., & Minx, J. (2007). A definition of ‘carbon footprint’. Ecological Economics Research Trends, 2, 55–65.
  Wu, X. M., Hu, S., & Mo, S. J. (2013). Carbon footprint model for evaluating the global warming impact of food transport refrigeration systems. Journal of Cleaner Production, 54, 115–124.CrossRef
  Xin, Y., Zhang, M., & Adhikari, B. (2014). The effects of ultrasound-assisted freezing on the freezing time and quality of broccoli (Brassica oleracea L. var. botrytis L.) during immersion freezing. International Journal of Refrigeration-Revue Internationale Du Froid, 41, 82–91.CrossRef
  Xu, Y.-Z., & Hu, Y.-S. (2011). Analys of the difference of carbon emissions of China’s manufacturing sector: a decomposition study based on input–output model. Software Science, 25(4), 69–74.
  Zhang, X., Inada, T., & Tezuka, A. (2003). Ultrasonic-induced nucleation of ice in water containing air bubbles. Ultrasonics Sonochemistry, 10(2), 71–76.CrossRef
  Zheng, L.Y., Sun, D.-W.(2004).Vacuum cooling for the food industry - a review of recent research advances. Trends in Food Science & Technology, 15(12), 1–8.
  Zheng, L., & Sun, D.-W. (2006). Innovative applications of power ultrasound during food freezing processes—a review. Trends in Food Science & Technology, 17(1), 16–23.CrossRef
  Ziegler, F., Winther, U., Hognes, E. S., Emanuelsson, A., Sund, V., & Ellingsen, H. (2013). The carbon footprint of Norwegian seafood products on the global seafood market. Journal of Industrial Ecology, 17(1), 103–116.CrossRef
  
• 作者单位：Zhongyue Xu (1)
  Da-Wen Sun (1) (2)
  Zhiwei Zhu (1)
  
  1. College of Light Industry and Food Sciences, South China University of Technology, Guangzhou, 510641, China
  2. Food Refrigeration and Computerized Food Technology, University College Dublin, Agriculture and Food Science Centre, National University of Ireland, Belfield, Dublin 4, Ireland
  
• 刊物类别：Chemistry and Materials Science
• 刊物主题：Chemistry
  Food Science
  Chemistry
  Agriculture
  Biotechnology
  
• 出版者：Springer New York
• ISSN：1935-5149

文摘

Since the food cold chain produces large amounts of greenhouse gases (GHGs), its carbon footprint (CF) has caused widespread concern. The process of freezing, one of the most common operations, is used in numerous food processes, and new freezing methods appear constantly. Ultrasound-assisted immersion freezing is an emerging technique that can significantly improve product quality compared to the conventional immersion freezing. In the current study, the CFs of conventional immersion freezing and ultrasound-assisted immersion freezing were investigated according to the principle of life cycle assessment (LCA). The freezing time of 1 mL of deionized water in a flask was 264 ± 15 s for conventional freezing, while the time of 1 mL of deionized water in a flask for the ultrasonic-assisted freezing could be lowered to 188 ± 5, 182 ± 5, 193 ± 6, and 201 ± 8 s under the four ultrasonic frequencies of 28, 40, 50, and 80 kHz, respectively. By improving heat transfer and enhancing ice nucleation, the freezing time of ultrasonic-assisted freezing was reduced significantly (P < 0.05) compared to conventional immersion freezing. In addition, electricity use and carbon emissions from electricity use at four frequency levels were reduced significantly (P < 0.05) compared to conventional immersion freezing. The final CFs of the freezing process for 1 mL of frozen water were 11.65 ± 0.52, 9.16 ± 0.24, 8.95 ± 0.17, 9.33 ± 0.22, and 9.60 ± 0.27E−5 kgCO₂eq (equivalent) for the control, 28, 40, 50, and 80 kHz, respectively. Most of the final product CF was related to electricity and the flask used, contributing 78.1 and 19.7 % respectively for the conventional freezing, and about 70 and 25 % respectively for the ultrasound-assisted freezing. This research demonstrated that ultrasonic-assisted freezing as an emerging technology could not only improve the food quality but can also reduce the CF of a product. In addition, sensitivity analysis showed that the use of flask and improving the electricity use efficiency could decrease the carbon emissions of the product significantly. Keywords Immersion freezing Ultrasound-assisted freezing Freezing unit Carbon footprint