Performance analysis of jig for coal cleaning using 3D response surface methodology 被引量：3

Performance analysis of jig for coal cleaning using 3D response surface methodology

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摘要 Beneficiation of coal of -4.76 mm + 3 mm size fraction was investigated in a laboratory model Denver jig.Process variables were studied to analyze their effect on the performance of jig in terms of yield and ash content of clean coal. Three-factor three-level Box-Behnken design of experiments with response surface methodology(RSM) was employed to understand the performance behavior of jig. From the study, the bed height was found to be the most significant parameter affecting the yield and ash content of clean coal. It was possible to reduce the ash content from 24.32% in feed to an ash content of 16.55% in clean coal at 2 L/min water flow rate and 10 min jigging time. Influence of operating variables of the jig on responses was presented and discussed in 3D surface plots. The developed model was found to be significant within the range of parameters under investigation with correlation of co-efficient values as 0.99(yield) and 0.98(ash). Beneficiation of coal of -4.76 mm ＋ 3 mm size fraction was investigated in a laboratory model Denver jig.Process variables were studied to analyze their effect on the performance of jig in terms of yield and ash content of clean coal. Three-factor three-level Box-Behnken design of experiments with response surface methodology（RSM） was employed to understand the performance behavior of jig. From the study, the bed height was found to be the most significant parameter affecting the yield and ash content of clean coal. It was possible to reduce the ash content from 24.32% in feed to an ash content of 16.55% in clean coal at 2 L/min water flow rate and 10 min jigging time. Influence of operating variables of the jig on responses was presented and discussed in 3D surface plots. The developed model was found to be significant within the range of parameters under investigation with correlation of co-efficient values as 0.99（yield） and 0.98（ash）.

作者 Kumar Shravan Venugopal R.

机构地区 Department of Fuel and Mineral Engineering

出处《International Journal of Mining Science and Technology》 SCIE EI CSCD 2017年第2期333-337,共5页 矿业科学技术学报（英文版）

关键词 Coal beneficiation Jigging Bed height 3D-RSM Box-Behnken 性能分析响应面法三维表面 Box-Behnken设计夹具选煤实验室模型灰分含量

分类号 TQ536 [化学工程—煤化学工程]

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参考文献2

1Noble Aaron,Luttrell Gerald H..A review of state-of-the-art processing operations in coal preparation[J].International Journal of Mining Science and Technology,2015,25(4):511-521. 被引量：7
2Ghasemi J.,Karamoozian M.,Sereshki F..Investigation of different coal types effect on the overall plant recovery[J].International Journal of Mining Science and Technology,2014,24(4):447-450. 被引量：1

二级参考文献44

1Ralston OC. Comparison of froth with the Trent process. Coal Age 1922;22- 23:91 1-4. 被引量：1
2Aplan FF. The historical development of coal flotation in the United States. Adv Flotation Technol 1999;2:269-87. 被引量：1
3Fiscor S. US prep plant census. Coal Age 2014;119:22-9. 被引量：1
4Honaker RQ, Davis H, Hollis R. Large diameter dmc performances in US preparation plants. In: Proceedings of 2014 Coal Prep Conference, Lexington, 2014. 被引量：1
5Galvin KP. Development of the reflux classifier. Challenges in Fine Coal Processing, Dewatering, and Disposal, SME. Englewood, vol. 10, 2012. 被引量：1
6Shih JS, Frey HC. Coal blending optimization under uncertainty. Eur J Oper Res 1995;83:452-65. 被引量：1
7Gupta V, Mohanty M, Mahajan A, Biswal SK. Genetic algorithms-a novel technique to optimize coal preparation plants. Int J Miner Process 2007;81:133-43. 被引量：1
8Luttrell GH, Noble A,Stanley F. Micro-price optimization of coal processing operations. In: Proceedings of 2014 SME Annual Meeting and Exhibit, USA, 2014. 被引量：1
9Noble A, Luttrell GH. Micro-pricing optimization: value-based partition curve analysis with applications to coal separation. In: Proceedings of 2015 SME Annual Meeting and Exhibit, USA, 2015. 被引量：1
10Bhattacharya 5. Rotary breakers: prospects of application in India. In: The First Asian Mining Congress, Kolkata, 2006. 被引量：1

共引文献6

1李振,王进,付艳红,周安宁,杨超,赵伟.气流粉碎过程的选择性特征及其数值模拟[J].中国矿业大学学报,2016,45(2):371-376. 被引量：5
2Zhang Jixiong,Zhang Qiang,Spearing A.J.S.(Sam),Miao Xiexing,Guo Shuai,Sun Qiang.Green coal mining technique integrating mining-dressing-gas draining-backfilling-mining[J].International Journal of Mining Science and Technology,2017,27(1):17-27. 被引量：16
3Sushanta Kumar Behera,Himanshu Meena,Sudipto Chakraborty,B.C.Meikap.Application of response surface methodology(RSM) for optimization of leaching parameters for ash reduction from low-grade coal[J].International Journal of Mining Science and Technology,2018,28(4):617-625. 被引量：12
4Adwek George,Boxiong Shen,Dongrui Kang,Jiancheng Yang,Jiangze Luo.Emission control strategies of hazardous trace elements from coal-fired power plants in China[J].Journal of Environmental Sciences,2020,32(7):66-90. 被引量：18
5陈宝兴,徐宁宁,林冬冬,王新文.耦合激励下的弛张筛面的动力学特性[J].中南大学学报（自然科学版）,2021,52(12):4201-4209. 被引量：3
6代伟,夏振兴,常俊林,李会军,杨春雨.基于CPS架构的煤炭清洁洗选过程控制创新实验平台[J].实验技术与管理,2022,39(9):119-126. 被引量：2

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1赵鹏,刘喜,霍永军.黑岱沟选煤厂跳汰机风阀系统参数调节效果分析[J].煤炭工程,2020,52(S02):67-70. 被引量：4
2曾红久,刘钦聚,王振龙.弧形筛二次造浆脱泥效果分析[J].洁净煤技术,2021,27(S01):62-66. 被引量：1
3F. Nakhaei,M.R. Mosavi,A. Sam.Recovery and grade prediction of pilot plant flotation column concentrate by a hybrid neural genetic algorithm[J].International Journal of Mining Science and Technology,2013,23(1):69-77. 被引量：6
4B.Shahbazi,B.Rezai,S.Chehreh Chelgani,S.M.Javad Koleini,M.Noaparast.Estimation of diameter and surface area flux of bubbles based on operational gas dispersion parameters by using regression and ANFIS[J].International Journal of Mining Science and Technology,2013,23(3):343-348. 被引量：4
5Ran Jincai,Liu Jiongtian,Zhang Chunjuan,Wang Dengyue,Li Xiaobing.Experimental investigation and modeling of flotation column for treatment of oily wastewater[J].International Journal of Mining Science and Technology,2013,23(5):665-668. 被引量：9
6谭文辉,李燕萍,许杨.微生物原生质体制备及再生的影响因素[J].现代食品科技,2006,22(3):263-265. 被引量：42
7朱芬,陈军,师亮,李玉祥,陈孝,赵明文.灵芝三萜高产菌株原生质体紫外诱变选育[J].南京农业大学学报,2008,31(1):37-41. 被引量：24
8毛雨,王丹,黄占斌,邢建民.微生物原生质体融合育种技术及其应用[J].中国生物工程杂志,2010,30(1):93-97. 被引量：21
9Atefeh Khaleghi,Sattar Ghader,Dariush Afzali.Ag recovery from copper anode slime by acid leaching at atmospheric pressure to synthesize silver nanoparticles[J].International Journal of Mining Science and Technology,2014,24(2):251-257. 被引量：7
10Ahmadi Rahman,Khodadadi Darban Ahmad,Abdollahy Mahmoud,Fan Maoming.Nano-microbubble flotation of fine and ultrafine chalcopyrite particles[J].International Journal of Mining Science and Technology,2014,24(4):559-566. 被引量：30

引证文献3

1Samiramis Nasirimoghaddam,Ali Mohebbi,Mohsen Karimi,M.Reza Yarahmadi.Assessment of pH-responsive nanoparticles performance on laboratory column flotation cell applying a real ore feed[J].International Journal of Mining Science and Technology,2020,30(2):197-205. 被引量：23
2孙佳星,杨红,孙晓东,郝然,张伟东,吕国忠.基于响应面法对香菇原生质体制备条件的优化[J].菌物学报,2022,41(5):837-846. 被引量：7
3胡金良.动力煤选煤厂宽尺度煤炭干法筛分-深度分选系统研究[J].中国煤炭,2024,50(4):126-137. 被引量：1

二级引证文献31

1聂文林,阳小勇,方建军,陈佳.基于混料设计和响应曲面法的云南某铜尾矿选铋工艺参数优化[J].金属矿山,2021(5):109-114. 被引量：4
2Liping Luo,Houqin Wu,Longhua Xu,Jinping Meng,Jiahui Lu,Huan Zhou,Xiaomei Huo,Lingyun Huang.An in situ ATR-FTIR study of mixed collectors BHA/DDA adsorption in ilmenite-titanaugite flotation system[J].International Journal of Mining Science and Technology,2021,31(4):689-697. 被引量：19
3廖寅飞,任厚瑞,安茂燕,赵一帆,郝晓栋.新型纳米粒子捕收剂强化低阶煤浮选机理[J].煤炭学报,2021,46(9):2767-2775. 被引量：12
4Weiyong Cui,Jianhua Chen.Insight into mineral flotation fundamentals through the DFT method[J].International Journal of Mining Science and Technology,2021,31(6):983-994. 被引量：8
5Jinpeng Cai,Peilun Shen,Dianwen Liu,Xiaolin Zhang,Jianjun Fang,Chao Su,Xingcai Yu,Jiangli Li,Han Wang.Growth of covellite crystal onto azurite surface during sulfurization and its response to flotation behavior[J].International Journal of Mining Science and Technology,2021,31(6):1003-1012. 被引量：9
6Shiqi Liu,Xumeng Chen,Yongjun Peng.Destabilising persistent coal froth using silicone oil[J].International Journal of Mining Science and Technology,2021,31(6):1023-1031.
7Zhouyueyang Cheng,Yimin Zhu,Yanjun Li,Stephen Butt.Experimental and MD simulation of 3-dodecyloxypropanamine and 3-tetradecyloxypropylamine adsorbed onto quartz(101) surface[J].International Journal of Mining Science and Technology,2021,31(6):1033-1042. 被引量：2
8Zhitao Yuan,Xuan Zhao,Jiwei Lu,Hong Lv,Lixia Li.Innovative pre-concentration technology for recovering ultrafine ilmenite using superconducting high gradient magnetic separator[J].International Journal of Mining Science and Technology,2021,31(6):1043-1052. 被引量：5
9Fangyuan Ma,Dongping Tao,Youjun Tao,Shuyong Liu.An innovative flake graphite upgrading process based on HPGR,stirred grinding mill, and nanobubble column flotation[J].International Journal of Mining Science and Technology,2021,31(6):1063-1074. 被引量：17
10Haiping Zhao,Renman Ruan,Xiaopeng Niu,Li Li,Enpu Zhang.A nanoscale qualitative study on the role of sodium hydrosulfide in oxidized carrollite flotation[J].International Journal of Mining Science and Technology,2021,31(6):1085-1093.

1张磊,黄欣.气候·热舒适·性能设计——微气候视野下的人居环境热性能研究[J].安徽建筑,2016,23(1):214-215.
2王伟明,胡洁,尹纪龙,彭颖红.An Intelligent Response Surface Methodology for Modeling of Domain Level Constraints[J].Journal of Shanghai Jiaotong university(Science),2006,11(1):27-33.
3赵庚新,时春风.可重复利用的机器人速换夹具[J].新产品世界,1994(9):21-21.
4张银龙,常大民.响应面法用于桁架体系可靠度分析[J].工程设计CAD与智能建筑,2002(11):57-60. 被引量：5
5李梦群,刘春美,裴葆青,蒋平.开放式夹具CAD系统[J].制造技术与机床,2000(2):23-24. 被引量：4
6袁新星,何雄科,袁星.加设翼墙RC框架结构抗倒塌试验研究[J].工程抗震与加固改造,2017,39(1):41-49. 被引量：1
7张越强.基于NX的夹具设计系统的研究与开发[J].中国机械,2015,0(7):192-193.
8孙兴俊.钢筋混凝土管道夹具吊装施工[J].市政技术,2013,31(S1):138-139. 被引量：1
9冷亚洪,李发陵.partial关键字在项目中的应用[J].科学咨询,2012(10):63-63.
10王珏.单柱式海上风能建筑结构物——循环力作用下砂性土孔隙水压力的研究[J].岩土力学,2008,29(4):1143-1146.

International Journal of Mining Science and Technology

2017年第2期

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