Technologies for utilization of industrial excess heat: Potentials for energy recovery and CO2 emission reduction

Energy Conversion and Management

Volumn 77, Issue , 2014, Pages 369-379

  Broberg Viklund, Sarah ^a   Johansson, Maria T ^a,b  

^a LINKÖPING UNIVERSITY   (Sweden)

^b UNIVERSITY OF GÄVLE   (Sweden)

Author keywords

CO2 emission; District heating; Electricity generation; Energy market scenarios; Heat recovery; Industrial excess heat

Indexed keywords

COMBINED HEAT AND POWER PRODUCTION; DISTRICT HEATING SYSTEM; ELECTRICITY GENERATION; EMISSION REDUCTION; EMISSIONS MITIGATION; ENERGY MARKET SCENARIOS; EXCESS HEATS; RECOVERY AND UTILIZATIONS;

CARBON DIOXIDE; COMMERCE; DISTRICT HEATING; ELECTRIC GENERATORS; EMISSION CONTROL; GALLIUM; INDUSTRY; RECOVERY; WASTE HEAT; WASTE HEAT UTILIZATION;

INDUSTRIAL EMISSIONS;

EID: 84887006516     PISSN: 01968904     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.enconman.2013.09.052     Document Type: Article

References (93)

1. EC (European Commission). Communication from the commission, Europe 2020 A strategy for smart, sustainable and inclusive growth. Brussels, Belgium; 2010.
2. EC (European Commission). Directive of the European parliament and of the council on energy efficiency 2011/1072 (COD). Brussels, Belgium; 2011.
3. SEA (Swedish Energy Agency). Policy instruments for industrial excess heat. (Styrmedel för industriell spillvärme) Report no. ER 2008:15. Eskilstuna, Sweden: Swedish Energy Agency; 2008 [in Swedish].
4. Thekdi A., Belt C. Waste heat reduction and recovery options for metal industry in The Minerals, Metals & Materials Society (TMS). Energy technology 2011: carbon dioxide and other greenhouse gas reduction metallurgy and waste heat recovery. John Wiley & Sons Inc; 2011. p. 17-24.
5. DOE (U.S. Department of Energy). Waste heat recovery: technology and opportunities in US Industry. US Department of Energy, BCS Incorporated; 2008.
6. M.T. Johansson, and M. Söderström Electricity generation from low temperature industrial excess heat - an opportunity for the steel industry Energ Effi 2013 10.1007/s12053-013-9218-6
7. 2 emissions Int J Energy Res 2012 10.1002/er.2905
8. J. Jönsson, I.-L. Svensson, T. Berntsson, and B. Moshfegh Excess heat from Kraft pulp mills: trade-offs between internal and external use in the case of Sweden - Part 2: Results for future energy market scenarios Energy Policy 36 11 2008 4186 4197
9. A. Wolf, M. Eklund, and M. Söderström Developing integration in a local industrial ecosystem - an explorative approach Bus Strategy Environ 16 2007 442 445 (Pubitemid 47408466)
10. Cronholm LÅ., Grönkvist S, Saxe M. Excess heat from industries and heat recovery from premises. (Spillvärme från industrier och lokaler) Report no. 2009:12. Swedish District Heating Association; 2009 [in Swedish].
11. S. Broberg, S. Backlund, M. Karlsson, and P. Thollander Industrial excess heat deliveries to Swedish district heating networks: drop it like it's hot Energy Policy 51 2012 332 339
12. Statistics Sweden. Demographic. < www.scb.se > [in Swedish].
13. Statistics Sweden. Energy. < www.scb.se > [in Swedish].
14. Swedish District Heating Association. Excess heat 2010 (Överskottsvärme 2010) Excel sheet accessed through personal communication; 2010 [in Swedish].
15. Ministry of the Environment. Constitution on environmental hazardous activities and, health; 1998: 899 [1998].
16. Axelsson E, Harvey S. Scenarios for assessing profitability and carbon balances of energy investments in industry - pathways to sustainable European energy systems. AGS Pathways report: 2010:EU1. Gothenburg, Sweden: AGS, The alliance for global sustainability; 2010.
17. E. Axelsson, S. Harvey, and T. Berntsson A tool for creating energy market scenarios for evaluation of investments in energy intensive industry Energy 34 12 2009 2069 2074
18. IEA (International Energy Agency). World Energy Outlook 2011; 2011.
19. Y.A. Çengel, R.H. Turner, and J.M. Cimbala Fundamentals of thermal-fluid sciences 3rd ed. 2008 Mc Graw-Hill Companies, Inc. New York
20. Y. Tian, and C.Y. Zhao A review of solar collectors and thermal energy storage in solar thermal applications Appl Energy 104 2013 538 553
21. Johansson MT, Wren J, Söderström M. Quantification and recovery of excess heat from cooling beds - a case study at a steel plant. Appl Energy; submitted for publication [2013].
22. Nilsson J. Heat recovery from cooling beds in the iron and steel industry: heat from the cooling beds - 100 times better than solar! (Värmeåtervinning från svalbäddar inom järn- och stålindustrin - Värme från svalbäddar - 100 gånger bättre än solvärme!) Report no. D809. Jernkontoret; 2003 [in Swedish].
23. K.J. Chua, S.K. Chou, and W.M. Yang Advances in heat pump systems: a review Appl Energy 87 2010 3611 3624
24. M.M. Farid, A.M. Khudhair, S.A.K. Razack, and S. Al-Hallaj A review on phase change energy storage: materials and applications Energy Convers Manage 45 2004 1597 1615
25. M.M. Farid, A.M. Khudhair, S.A.K. Razack, and S. Al-Hallaj A review on phase change energy storage: materials and applications Energy Convers Manage 45 2004 1597 1615
26. S.M. Hasnain Review on sustainable thermal energy storage technologies, Part I: Heat storage materials and techniques Energy Convers Manage 39 11 1998 1127 1138 (Pubitemid 128420382)
27. B. Zalba, J.M. Marín, L.F. Cabeza, and H. Mehling Review on thermal energy storage with phase change: materials, heat transfer analysis and applications Appl Therm Eng 23 2003 251 283 (Pubitemid 35460092)
28. Ericsson K. Introduction and development of the Swedish district heating system - Critical factors and lessons learned. Report as a part of the IEE project "Policy development for improving RES-H/C penetration in European Member States". Lund University, Lund, Sweden; 2009.
29. B. Rezaie, and M.A. Rosen District heating and cooling: review of technology and potential enhancements Appl Energy 93 2011 2 10
30. Optensys Energianalys AB. Proposal for accounting of excess heat when designing new district heating systems. (Förslag till princip för redovisning av restvärmepotential vid projektering av ny fjärrvärmeproduktion) Linköping, Sweden: Optensys; 2012 [in Swedish].
31. Frederiksen S., Werner S. District heating, theory, technology and function. (Fjärrvärme: teori, teknik och funktion) Studentlitteratur, Lund, Sweden; 1993 [In Swedish].
32. Wiltshire R. Low temperature district energy systems. In: Proceedings of 16th building services, mechanical and building industry days international conference, Debrecen, Hungary; 14-15 October 2011.
33. A.N. Ajah, A.C. Patil, P.M. Herder, and J. Grievink Integrated conceptual design of a robust and reliable waste-heat district heating system Appl Therm Eng 27 2007 1158 1164 (Pubitemid 46162215)
34. Rydstrand M, Martin V, Westermark M. Heat driven cooling. (Värmedriven kyla) Report no. FOU 2004:112. Stockholm, Sweden: Swedish District Heating Association; 2004 [in Swedish].
35. L. Trygg, and S. Amiri European perspective on absorption cooling in combined heat and power system - a case study on energy utility and industries in Sweden Appl Energy 88 12 2007 1319 1337 (Pubitemid 47348171)
36. Lindmark S. The Role of Absorption Cooling for Reachin Sustaniable Energy Systems. Licentiate thesis, Royal Institute of Technology, Stockholm, Sweden; 2005.
37. P. Srikhirin, S. Aphornratana, and S. Chungpaibulpatana A review of absorption refrigeration technologies Renew Sustain Energy Rev 5 2001 343 372 (Pubitemid 32610522)
38. Svensson IL. Evaluating system concequences of energy-co-operation between industries and utilities. Linköping studies in science and technology, dissertation nr. 1407, Linköping University, Linköping, Sweden; 2011.
39. M. Martin, and M. Eklund Improving the environmental performance of biofuels with industrial symbiosis Biomass Bioenergy 35 2011 1747 1755
40. N.B. Jacobsen Industrial symbiosis in kalundborg, Denmark: a quantitative assessment of economic and environmental aspects J Ind Ecol 10 1-2 2006 239 255 (Pubitemid 44689547)
41. A. Wolf Energy-efficient pellet production in the forest industry - a study of obstacles and success factors Biomass Bioenergy 30 2006 38 45
42. Ellersdorfer M, Weiss C. Integration of biogas plants in the building materials industry. In: Proceedings of WREC, Linköping, Sweden, 8-13 May; 2011.
43. H. Li, Q. Chen, X. Zhang, K.N. Finney, V.N. Sharifi, and J. Swithenbank Evaluation of a biomass drying process using waste heat from process industries: a case study Appl Therm Eng 35 2012 71 80
44. D. Chinese, A. Meneghetti, and G. Nardin Waste-to-energy based greenhouse heating: exploring viability conditions through optimization models Renewable Energy 30 2005 1573 1586
45. R. Andrews, and J.M. Pearce Environmental and economic assessment of greenhouse waste heat exchange J Cleaner Prod 19 2011 1446 1454
46. Andersson V, Broberg S, Hackl R. 2012. Integrated algae cultivation for municipal wastewater treatment and biofuels production in industrial clusters. In: Proceedings of WREF, Denver, USA, 13-17 May; 2012.
47. E. Fahlén, L. Trygg, and E.O. Ahlgren Assessment of absorption cooling as a district heating system strategy - a case study Energy Convers Manage 60 2012 115 124
48. R. Law, A. Harvey, and D. Reay Opportunities for low-grade heat recovery in the UK food processing industry Appl Therm Eng 2012 10.1016/j.applthermaleng. 2012.03.024
49. US department of Energy. Waste heat recovery: technology and opportunities in US industry; 2008 < www1.eere.energy.gov/manufacturing/ intensiveprocesses/pdfs/waste-heat-recovery.pdf >.
50. T.Q. Nguyen, J.D. Slawnwhite, and K.G. Boulama Power generation from residual industrial heat Energy Convers Manage 51 2010 2220 2229
51. M.Z. Stijepovic, P. Linke, A.I. Papadopoulos, and A.S. Grujic On the role of working fluid properties in organic rankine cycle performance Appl Therm Eng 36 2012 406 413
52. S. Quoilin, S. Declaye, B.F. Tchanche, and V. Lemort Thermo-economic optimization of waste heat recovery organic rankine cycles Appl Therm Eng 31 2011 2885 2893
53. B.-T. Liu, K.-H. Chien, and C.-C. Wang Effect of working fluids on organic Rankine cycle for waste heat recovery Energy 29 2004 1207 1217 (Pubitemid 38616238)
54. Y. Dai, J. Wang, and L. Gao Parametric optimization and comparative study of organic Rankine cycle (ORC) for low grade waste heat Energy Convers Manage 50 2009 576 582
55. F. Vélez, F. Chejne, G. Antolin, and A. Quijano Theoretical analysis of a transcritical power cycle for power generation from waste energy at low temperature heat source Energy Convers Manage 60 2012 188 195
56. T. Guo, H. Wang, and S. Zhang Comparative analysis of natural and conventional working fluids for use in transcritical Rankine cycle using low-temperature geothermal source Int J Energy Res 35 6 2011 530 544
57. F. Ayachi, E.B. Ksayer, and P. Neveu Exergy assessment of recovery solutions from dry and moist gas available at medium temperature Energies 5 3 2012 718 730
58. 2 capture Int J Greenhouse Gas Control 12 2013 213 219
59. Kasap S. Thermoelectric effects in metals: thermocouples; 2001. < http://kasap3.usask.ca/samples/Thermoelectric-Seebeck.pdf >.
60. C. Hadjustassou, E. Kyriakides, and J. Georgiou Designing high efficiency segmented thermoelectric generators Energy Convers Manage 66 2013 165 172
61. D.M. Rowe General principles and basic considerations in thermoelectric handbook from macro to nano 2005 CRC Press: e-book p. 1.4-1.14
62. K. Qiu Hayden ACS integrated thermoelectric and organic rankine cycles for micro-CHP systems Appl Energy 2012 10.1016/j.apenergy.2011.12.072
63. D.L. Chubb Fundamentals of thermophotovoltaic energy conversion 2007 Elsevier Amsterdam
64. A. Luque, and S. Hegedus Handbook of photovoltaic science and engineering. 2nd ed 2011 John Wiley & Sons
65. R. Ramakumar, A.M. Barnett, L.L. Kazmerski, J.P. Benner, and T.J. Coutts Power systems and generation R.C. Dorf, The electrical engineering handbook 2000 CRC Press Boca Raton [Available electronic at: ENGnetBASE]
66. Z. Utlu, and U. Parali Investigation of the potential of thermophotovoltaic heat recovery for the Turkish industrial sector Energy Convers Manage 74 2013 308 322
67. T. Bauer, I. Forbes, and N. Pearsall The potential of thermophotovoltaic heat recovery for the UK industry Int J Ambient Energy 25 2004 19 25
68. A. De Pascale, C. Ferrari, F. Melino, M. Morini, and M. Pinelli Integration between a thermophotovoltaic generator and an organic Rankine cycle applied Energy 97 2012 695 703
69. K. Qiu, and A.C.S. Hayden Development of a novel cascading TPV and TE power generation system Appl Energy 91 1 2012 304 308
70. Persson C, Olsson J. Comparison of various co-generation technologies. (Jämförelse mellan olika kraftvärmeteknologier) Report no. SGC 128. Malmö, Sweden: Swedish Gas Technology Centre; 2002 [in Swedish].
71. X.Q. Kong, R.Z. Wang, and X.H. Huang Energy efficiency and economic feasibility of CCHP driven by stirling engine Energy Convers Manage 45 9-10 2004 1433 1442
72. SLU (Swedish University of Agricultural Science). Profitability of Small-Scale Combined Heat and Power Production Using Biofuels - Conditions and Future Prospects. (Lönsamhet för småskalig biobrä nslebaserad kraftvärme - förutsättningar och framtidsutsikter) Report no. 033. Uppsala, Sweden: Swedish University of Agricultural Science; 2011 [in Swedish].
73. R.S. Moghadam, H. Sayyaadi, and H. Hosseinzade Sizing a solar dish Stirling micro-CHP system for residential application in diverse climatic conditions based on 3E analysis Energy Convers Manage 75 2013 348 365
74. T. Li, D.W. Tang, Z. Li, J. Du, T. Zhou, and Y. Jia Development and test of a Stirling engine driven by waste gases for micro-CHP system Appl Therm Eng 33-34 2012 119 123
75. S.T. Hsu, F.Y. Lin, and J.S. Chiou Heat-transfer aspects of Stirling power generation using incinerator waste energy Renewable Energy 28 2003 59 69
76. Exencotech. < www.exencotech.se > [accessed 01.03.13].
77. Östlund B. CEO of Exencotech AB. Personal communication [30.11.11].
78. Hansson H, Larsson S-E, Nyström O, Olsson F, Ridell B. Electricity from new facilities 2007 - a comparison between different technologies for electricity generation with regard to costs and development prospects (El från nya anläggningar 2007 - Jämförelse mellan olika tekniker för elgenerering med avseende på kostnader och utvecklingstendenser). Report no. 07:50. Stockholm, Sweden: Elforsk; 2007 [In Swedish].
79. Brodén H, Nyström O, Jönsson M. Optimum power yield for bio fuel fired combined heat and power plants (Optimal elverkningsgrad för biobränsleeldade kraftvärmeverk). Anläggnings- och förbränningsteknik 1236. Stockholm, Sweden: Värmeforsk; 2012 (in Swedish).
80. F. Vélez, J.J. Segovia, M.C. Martín, G. Antolín, F. Chejne, and A. Quijano A technical, economical and market review of organic Rankine cycles for the conversion of low-grade heat for power generation Renew Sustain Energy Rev 16 6 2012 4175 4189
81. S. Ogriseck Integration of Kalina cycle in a combined heat and power plant, a case study Appl Therm Eng 29 2009 2843 2848
82. X. Zhang, M. He, and Y. Zhang A review of research on the Kalina cycle Renew Sustain Energy Rev 16 7 2012 5309 5318
83. P. Bombarda, C.M. Invernizzi, and C. Pietra Heat recovery from diesel engine: a thermodynamic comparison between Kalina and ORC cycles Appl Therm Eng 30 2010 212 219
84. Ventosa i Capell V., Tarragó S., Maria J. Analysis of possibilities for 1 MW electricity generation from waste heat in the port of Rotterdam. Master thesis, Universitat Politécnica de Catalunya, Barcelona, Spain; 2011.
85. Z.H. Dughaish Lead telluride as a thermoelectric material for thermoelectric power generation Physica B: Condens Matter 322 1-2 2002 205 223
86. E.D. Rogdakis, G.D. Antonakos, and I.P. Koronaki Thermodynamic analysis and experimental investigation of a Solo V161 Stirling cogeneration unit Energy 45 1 2012 503 511
87. C.-L. Chen, C.-E. Ho, and H.-T. Yau Performance analysis and optimization of a solar powered stirling engine with heat transfer considerations Energies 5 9 2012 3573 3585
88. Cool Energy Inc. < www.coolenergyinc.com/ > [accessed 25.04.13].
89. The Engineering Toolbox. Water - thermal properties. < www.engineeringtoolbox.com/water-thermal-properties-d-162.html > [accessed 16.08.13].
90. Pipeflow calculations. Flue gases properties table - density, viscosity. < www.pipeflowcalculations.com/tables/flue-gas.php > [accessed 02.04.13].
91. Asp B, Wiklund M, Dahl J. Utilisation of excess energy from the steel industry for electricity production: an effective utilisation of resources for electricity production. (Användning av stålindustrins restenergier för elproduktion: Ett effektivt resursutnyttjande för elproduktion) Report no. JK 98400. Stockholm, Sweden: Jernkontoret; 2008 [in Swedish].
92. Pernecker G. Uhlig S. Low-enthalpy power generation with ORC-turbogenerator, the Altheim project, upper Austria. GHC Bulletin; 2002. < http://geoheat.oit.edu/bulletin/bull23-1/art6.pdf >.
93. Y. Ammar, S. Joyce, R. Norman, Y. Wang, and A.P. Roskilly Low grade thermal energy sources and uses from the process industry in the UK Appl Energy 89 1 2012 3 20.