Exergy Analysis and Optimization of Ladle Furnace Refining Process 被引量：2

Exergy Analysis and Optimization of Ladle Furnace Refining Process

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摘要 To decrease energy consumption of ladle furnace, exergy analysis and optimization were conducted based on the ladle furnace refining process of modern clean steelmaking. Exergy analysis results showed that exergy loss induced by unavailable electric energy is the largest, and the electric energy efficiency is 46.20%. To cut down the unavailable electric energy, industrial experiments of submerged arc heating were carried out combined with slag composition modification. Results showed that submerged arc heating can be achieved within most heating period, average heating rate increased by 0. 5 ℃/min, unavailable electric energy decreased by 21. 730 MJ per ton steel, and electric energy efficiency was enhanced by 14.84 %. As the refining cycle was shortened, the exergy loss induced by heat elimination decreased from 19. 455 MJ per ton steel to 11. 066 MJ per ton steel. To decrease energy consumption of ladle furnace, exergy analysis and optimization were conducted based on the ladle furnace refining process of modern clean steelmaking. Exergy analysis results showed that exergy loss induced by unavailable electric energy is the largest, and the electric energy efficiency is 46.20%. To cut down the unavailable electric energy, industrial experiments of submerged arc heating were carried out combined with slag composition modification. Results showed that submerged arc heating can be achieved within most heating period, average heating rate increased by 0. 5 ℃/min, unavailable electric energy decreased by 21. 730 MJ per ton steel, and electric energy efficiency was enhanced by 14.84 %. As the refining cycle was shortened, the exergy loss induced by heat elimination decreased from 19. 455 MJ per ton steel to 11. 066 MJ per ton steel.

作者 MIN Yi JIANG Mao-fa

机构地区 School ofMaterials and Metallurgy

出处《Journal of Iron and Steel Research International》 SCIE EI CAS CSCD 2010年第11期24-28,共5页

关键词 LF exergy analysis exergy loss submerged arc heating LF exergy analysis exergy loss submerged arc heating

分类号 TF769.2 [冶金工程—钢铁冶金] TK124 [动力工程及工程热物理—工程热物理]

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2010年第11期

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