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Energies 2020, 13, 6096 18 of 24 33. Caglayan, H.; S ̧öhret, Y.; Caliskan, H. Thermo-Ecologic Evaluation of a Spray Dryer for Ceramic Industry. Energy Procedia 2018, 144, 164–169. [CrossRef] 34. Hasanuzzaman, M.; Rahima, N.A.; Hosenuzzaman, M.; Saidur, R.; Mahbubul, I.M. Energy savings in the combustion-based process heating in industrial sector. Renew. Sustain. Energy Rev. 2012, 16, 4527–4536. [CrossRef] 35. Saidur, R. A review on electrical motors energy use and energy savings. Renew. Sustain. Energy Rev. 2010, 14, 877–898. [CrossRef] 36. Hassan, A.; Eldrup, N.H.; Normann, F.; Andersson, V.; Skagestad, R.; Mathisen, A.; Øi, L.E. Cost estimation of heat recovery networks for utilization of industrial excess heat for carbon dioxide absorption. Int. J. Greenh. Gas Control 2018, 74, 219–228. 37. Hektor, E.; Berntsson, T. Future CO2 removal from pulp mills-process integration consequences. Energy Convers. Manag. 2007, 48, 3025–3033. [CrossRef] 38. Hegerland, G.; Pande, J.; Haugen, H.A.; Eldrup, N.; Tokheim, L.A.; Hatlevik, L.V. Capture of CO2 from a cement plant—Technical possibilities and economical estimates. In Proceedings of the 8th International Conference on Greenhouse Gas Control Technologies, Trondheim, Norway, 19–22 June 2006. 39. Andersson, V.; Franck, P.Å.; Berntsson, T. Techno-economic analysis of excess heat driven post-combustion CCS at an oil refinery. Int. J. Greenh. Gas Control 2016, 45, 130–138. [CrossRef] 40. Johansson, D.; Sjöblom, J.; Berntsson, T. Heat supply alternatives for CO2 capture in the process industry. Int. J. Greenh. Gas Control 2012, 8, 217–232. [CrossRef] 41. Reddy, C.; Maidu, S.; Rangaish, G.P. Waste Heat Recovery Methods and Technologies. Chemical Engineering. New York; McGraw-Hill. Chem. Week Publ. 2013, 120, 28–38. 42. Rozpondek, M.; Wne ̨k, M. The Application Aspects of Self-Recuperative and Self-Regenerative Burners in Thermal Devices. Available online: https://www.mtf.stuba.sk/buxus/docs/internetovy_casopis/2013/1/3_ Rozpondek_Wnek.pdf (accessed on 28 August 2019). 43. Elmabrouk, E.M. Enhance the Heat Transfer in a Heat Treatment Furnace through Improving the Combustion Process in the Radiation Tubes. Ph.D. Thesis, University of Sheffield, Sheffield, UK, 2011. 44. Gitzinger, H.P.; Wicker, M.; Ballinger, P. Saving energy by modernizing the heating system, using modern self-recuperative burners. Heat Process. 2010, 8, 253–256. Available online: https://furnace-online.com/en/ uploadha/2017/10/principle-of-self-recuperator-burner.pdf (accessed on 28 August 2019). 45. ESA Pyronics International. Self-recuperative Burners High Speed Free Flame, Pyronics International—SAID Group. 2015. Available online: http://www.esapyronics.com/wp-content/uploads/2014/12/E3901FE.pdf (accessed on 28 August 2019). 46. Danieli Centro Combustion. Available online: http://www.danielicentrocombustion.it/burners-direct-self- recuperative.html (accessed on 10 April 2020). 47. Tangjitsicharoen, S.; Ratanakuakangwan, S.; Khonmeak, M.; Fuangworawong, N. Investigation of Regenerative and Recuperative Burners for Different Sizes of Reheating Furnaces. Int. J. Mech. Mechatron. 2013, 7, 2027–2031. 48. The Institute for Industrial Productivity. Regenerative Burners for Reheating Furnaces. 2017. Available online: http://ietd.iipnetwork.org/content/regenerative-burners-reheating-furnaces (accessed on 18 September 2020). 49. Gonzalez, J.C.M.; Nunes, M.P. Turbulence Promoters for Heat Transfer Enhancement. Prog. Petrochem. Sci. 2018. [CrossRef] 50. Industrial Efficiency Technology Database. Available online: www.iipinetwork.org/wp-content/Ietd/content/ regenerative-burners-reheating-furnaces.html (accessed on 10 April 2020). 51. Maloney, N.; Wroe, R. Dual fuel firing of Ceramics. Ziegelind. Int. 1994, 4, 209–211. 52. Sumer, G.; Rozak, S.; Gallimore, P.; Green, P.; Tordoff, J.; Kos, G.; Dahlman, G. Proper selection of kiln furniture. Am. Ceram. Soc. Bull 1995, 74, 54–65. 53. Matthews, S.; Pickell, G. A new generation of low-mass kiln furniture. Am. Ceram. Soc. Bull 1999, 78, 77–78. 54. Thermopedia. Available online: http://www.thermopedia.com/content/711 (accessed on 7 October 2019). 55. Keith Engineering. Airless Drying Technology. Available online: https://keitheng.com.au/new-technology/ airless-drying (accessed on 28 August 2019). 56. Naik-Dhungel, N. Waste Heat to Power Systems. 2012. Available online: https://www.epa.gov/sites/ production/files/2015-07/documents/waste_heat_to_power_systems.pdf (accessed on 28 August 2019).PDF Image | Ceramic Sector Focusing on Waste Heat Recovery
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