Resumo
O objetivo desta pesquisa foi realizar uma revisão da literatura sobre práticas sustentáveis plausíveis de serem aplicadas aos processos de fundição e realizar um estudo de caso auxiliado por uma entrevista. Foi possível identificar 5 práticas sustentáveis possíveis de serem aplicadas no referido processo e que boa parte das mesmas são aplicadas na empresa selecionada para o estudo de caso.
Referências
Salonitis K, Zeng B, Mehrabi HA, Jolly M. The Challenges for Energy Efficient Casting Processes. Procedia CIRP [Internet]. Elsevier B.V.; 2016;40:24–9.
Singh G, Siddique R. Effect of waste foundry sand (WFS) as partial replacement of sand on the strength, ultrasonic pulse velocity and permeability of concrete. Constr Build Mater [Internet]. Elsevier Ltd; 2012;26(1):415–22.
Yazoghli-Marzouk O, Vulcano-Greullet N, Cantegrit L, Friteyre L, Jullien A. Recycling foundry sand in road construction-field assessment. Constr Build Mater [Internet]. Elsevier Ltd; 2014;61:69–78.
Lazzarin RM, Noro M. Energy efficiency opportunities in the production process of cast iron foundries: An experience in Italy. Appl Therm Eng [Internet]. Elsevier Ltd; 2015;90:509–20.
Kipepe TM, Pan X. Energy improvement in induction furnace using foaming slag with variation of carbon injection. J Energy South Africa. 2015;26(2):64–73.
Matsuura H, Fruehan RJ. Slag Foaming in an Electric Arc Furnace. ISIJ Int [Internet]. 2009;49(10):1530–5.
Pagone E, Jolly M, Salonitis K. The Development of a Tool to Promote Sustainability in Casting Processes. Procedia CIRP. The Author(s); 2016;55:53–8.
Salonitis K, Jolly MR, Zeng B, Mehrabi H. Improvements in energy consumption and environmental impact by novel single shot melting process for casting. J Clean Prod [Internet]. Elsevier Ltd; 2016;137:1532–42.
Zeng B, Jolly M, Salonitis K. Manufacturing cost modeling of castings produced with CRIMSON process. TMS Annu Meet. 2014;201–8.
Salonitis K, Jolly M, Zeng B. Simulation Based Energy and Resource Efficient Casting Process Chain Selection: A Case Study. Procedia Manuf. The Author(s); 2017;8(October 2016):67–74.
Hasanbeigi A, Arens M, Price L. Alternative emerging ironmaking technologies for energyefficiency and carbon dioxide emissions reduction: A technical review. Renew Sustain Energy Rev [Internet]. Elsevier; 2014;33:645–58.
Arulrajah A, Yaghoubi E, Imteaz M, Horpibulsuk S. Recycled waste foundry sand as a sustainable subgrade fill and pipe-bedding construction material: Engineering and environmental evaluation. Sustain Cities Soc [Internet]. Elsevier B.V.; 2017;28:343–9. 13. Bhardwaj B, Kumar P. Waste foundry sand in concrete: A review. Constr Build Mater [Internet]. Elsevier Ltd; 2017;156:661–74. 14. Forbes SL, De Silva T. Analysis of environmental management systems in New Zealand wineries. Int J Wine Bus Res [Internet]. 2012;24(2):98–114.
Singh G, Siddique R. Effect of waste foundry sand (WFS) as partial replacement of sand on the strength, ultrasonic pulse velocity and permeability of concrete. Constr Build Mater [Internet]. Elsevier Ltd; 2012;26(1):415–22.
Yazoghli-Marzouk O, Vulcano-Greullet N, Cantegrit L, Friteyre L, Jullien A. Recycling foundry sand in road construction-field assessment. Constr Build Mater [Internet]. Elsevier Ltd; 2014;61:69–78.
Lazzarin RM, Noro M. Energy efficiency opportunities in the production process of cast iron foundries: An experience in Italy. Appl Therm Eng [Internet]. Elsevier Ltd; 2015;90:509–20.
Kipepe TM, Pan X. Energy improvement in induction furnace using foaming slag with variation of carbon injection. J Energy South Africa. 2015;26(2):64–73.
Matsuura H, Fruehan RJ. Slag Foaming in an Electric Arc Furnace. ISIJ Int [Internet]. 2009;49(10):1530–5.
Pagone E, Jolly M, Salonitis K. The Development of a Tool to Promote Sustainability in Casting Processes. Procedia CIRP. The Author(s); 2016;55:53–8.
Salonitis K, Jolly MR, Zeng B, Mehrabi H. Improvements in energy consumption and environmental impact by novel single shot melting process for casting. J Clean Prod [Internet]. Elsevier Ltd; 2016;137:1532–42.
Zeng B, Jolly M, Salonitis K. Manufacturing cost modeling of castings produced with CRIMSON process. TMS Annu Meet. 2014;201–8.
Salonitis K, Jolly M, Zeng B. Simulation Based Energy and Resource Efficient Casting Process Chain Selection: A Case Study. Procedia Manuf. The Author(s); 2017;8(October 2016):67–74.
Hasanbeigi A, Arens M, Price L. Alternative emerging ironmaking technologies for energyefficiency and carbon dioxide emissions reduction: A technical review. Renew Sustain Energy Rev [Internet]. Elsevier; 2014;33:645–58.
Arulrajah A, Yaghoubi E, Imteaz M, Horpibulsuk S. Recycled waste foundry sand as a sustainable subgrade fill and pipe-bedding construction material: Engineering and environmental evaluation. Sustain Cities Soc [Internet]. Elsevier B.V.; 2017;28:343–9. 13. Bhardwaj B, Kumar P. Waste foundry sand in concrete: A review. Constr Build Mater [Internet]. Elsevier Ltd; 2017;156:661–74. 14. Forbes SL, De Silva T. Analysis of environmental management systems in New Zealand wineries. Int J Wine Bus Res [Internet]. 2012;24(2):98–114.
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