喷吹煤气高炉冶炼的极限焦比研究
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摘要
本文提出用煤气代替煤粉进行喷吹,简化了高炉冶炼过程,使得喷吹煤气的高炉冶炼达到焦比极限成为可能。应用焦比与直接还原度的联合计算方法,研究了喷吹煤气新工艺下的极限焦比值。结果指出:煤气仅进行间接还原时,高炉冶炼1000 kg生铁的总耗热为1506849.53 k J/t Fe,焦比为238.88 kg/t Fe,直接还原度为0.20。而煤气在风口区燃烧提供热量时,高炉冶炼1000 kg生铁的总耗热为1873112.57 kJ/tFe,焦比为258.89 kg/tFe,直接还原度为0.34。当喷入的煤气一部分在风口区燃烧供热和一部分在间接还原区进行间接还原时,喷煤气高炉才能达到极限焦比值。直接还原度和极限焦比都随着喷入的煤气量的增加而先减小后增大。计算得到喷煤气高炉的极限焦比值为124.76 kg/tFe,喷入的煤气量为1127.97 m3/tFe,直接还原度可降到0.044,新工艺冶炼需要的单位生铁总热量为1074599.9 kJ/tFe。
This paper presents using the gas-injection to instead of coal. It simplifies the smelting process,and provides possibilities for reaching the limit of coke rate. The limit of the new technology of the gasinjection BF was studied with the method of joint computing using the coke rate and direct reduction degree.The results show that when the gas only carries out the indirect reduction, the total thermal consumption of smelting 1000 kg iron is 1506849.53 kJ/tFe, the coke rate is 238.88 kg/tFe, and the direct reduction degree is0.20. When the gas burns in the tuyere area to provide heat, the total thermal consumption of smelting 1000 kg iron is 1873112.57 kJ/tFe, the coke rate is 258.89 kg/tFe, and the direct reduction degree is 0.34. When a part of gas in tuyere area combust and provide heat and a part of gas carry out the indirect reduction, the gas-injection blast furnace smelting can reach the limit value. The direct reduction degree and limit coke rate both decrease firstly and then increase with the amount of gas-injection increase. The coke rate limit value in the gas-injection blast furnace is 124.76 kg/t. The amount of gas-injection is 1127.97 m3/tFe, and the direct reduction degree can be reduced to 0.044, the total thermal consumption of smelting 1000 kg iron is1074599.9 kJ/tFe under the new process conditions.
This paper presents using the gas-injection to instead of coal. It simplifies the smelting process,and provides possibilities for reaching the limit of coke rate. The limit of the new technology of the gasinjection BF was studied with the method of joint computing using the coke rate and direct reduction degree.The results show that when the gas only carries out the indirect reduction, the total thermal consumption of smelting 1000 kg iron is 1506849.53 kJ/tFe, the coke rate is 238.88 kg/tFe, and the direct reduction degree is0.20. When the gas burns in the tuyere area to provide heat, the total thermal consumption of smelting 1000 kg iron is 1873112.57 kJ/tFe, the coke rate is 258.89 kg/tFe, and the direct reduction degree is 0.34. When a part of gas in tuyere area combust and provide heat and a part of gas carry out the indirect reduction, the gas-injection blast furnace smelting can reach the limit value. The direct reduction degree and limit coke rate both decrease firstly and then increase with the amount of gas-injection increase. The coke rate limit value in the gas-injection blast furnace is 124.76 kg/t. The amount of gas-injection is 1127.97 m3/tFe, and the direct reduction degree can be reduced to 0.044, the total thermal consumption of smelting 1000 kg iron is1074599.9 kJ/tFe under the new process conditions.
引文
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[2]杨天钧,张建良.我国炼铁生产的方向:高效节能环保低成本[J].炼铁,2014,33(3):1-11.
[3]曹枫,龙世刚.高炉喷吹废塑料技术及应用前景[J].冶金能源,2001(9):26-29.
[4]李博知,尹国才,秦学武.中国高炉喷吹塑料的可行性分析[J].中国冶金,2006,16(6):47-53.
[5]Gielen D,Moriguchi Y.CO2 in the iron and steel industry:an analysis of Japanese emission reduction potentials[J].Energy Policy,2002,30(10):849-863.
[6]Price L,Sinton J,Worrell E,et al.Energy use and carbon dioxide emissions from steel production in China[J].Energy,2002,27(5):429-446.
[7]Fink F.Suspension smelting reduction-a new method of hot iron production[J].Steel Times(UK),1996,224(11):398-399.
[8]K L W.Use of Sponge Iron in Ironmaking[J].Scandinavian Journal of Metallurgy,1993,22(3):6.
[9]Ma J E J O.The Balanced Oxygen Blast Furnace(BOBF)Ironmaking Process[J].Scandinavian Journal of Metallurgy,1992,21(3):8.
[10]王成善,时艳文,李丹丹,等.全氧高炉炼铁工艺模拟分析[J].重庆大学学报,2014,37(9):47-58.
[11]邵久刚,张建良,王广伟,等.高炉全氧炼铁工艺理论分析[J].冶金能源.2013,32(4):22-28.
[12]董择上,薛庆国,左海滨,等.氧气高炉喷吹焦炉煤气数学模型[J].钢铁,2017,52(4):18-24.
[13]郭同来,储满生,柳政根,等.高炉喷吹焦炉煤气操作的?分析[J].中南大学学报:自然科学版,2013,44(8):3108-3114.
[14]周亮,刘克明,沙永志.高炉喷吹焦炉煤气置换比的计算[J].钢铁研究学报,2013,25(5):19-23.
[15]陈永星,王广伟,张建良,等.高炉富氧喷吹焦炉煤气理论研究[J].钢铁,2012,47(2):13-16.
[16]李昊堃,刘克明,沙永志.高炉喷吹焦炉煤气工艺分析[J].炼铁,2011,30(2):59-62.
[17]Kenichi H,Shinroku M,Akihiko S,等.高炉喷吹改质焦炉煤气减少CO2排放的技术发展[J].世界钢铁,2013(4):5-9.
[18]李福民.喷吹煤气高炉的炉料同化过程研究[D].沈阳:东北大学,2009.
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