ZGM113G型煤磨机提产改造应用实践

doi:10.19698/j.cnki.1001-6171.20234047

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摘要

ZGM113G型立式磨煤机存在磨内压差高、振动值偏大、吐渣量大、研磨效率低、产量无法满足水泥生产要求等问题，通过分析研判煤磨机实际运行工况和提产内外部影响因素，采取了加设热风沉降室、改造研磨区域、改造选粉机等改造措施。改造后，系统运行稳定，吐渣量减少，设备故障率降低，磨机产量由35t/d提高至45t/h，提产幅度为28.5%；磨机主电机电流降低了9A，稳定在65A左右，主电机电耗降低0.5 kW?h/t。

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	郭永强

关键词: 煤磨机热风沉降室研磨区域提产降耗

Abstract:

The ZGM113G vertical coal mill has some problems such as high pressure difference in grinding, large vibration value, large slag discharge, low grinding efficiency, and the output cannot meet the requirements of cement production. Based on the analysis and analysis of the actual operating conditions of the coal mill and the internal and external factors affecting the production, some measures were taken, such as adding a hot air settling chamber, reforming the grinding area and reforming the powder separator. After the transformation, the system runs stably, the slag spitting amount is reduced, the equipment failure rate is reduced, the mill output is increased from 35t/d to 45t/h, the yield increase is 28.5%; The main motor current of the mill is reduced by 9A and stabilized at about 65A, and the power consumption of the main motor is reduced by 0.5kW?h/t.

Key words: coal mill hot air settling chamber grinding area increase production and reduce consumption

收稿日期: 2022-12-05 修回日期: 2023-07-25 出版日期: 2023-07-25 发布日期: 2023-07-25 整期出版日期: 2023-07-25

ZTFLH:

TQ172.6

引用本文:

郭永强. ZGM113G型煤磨机提产改造应用实践[J]. 水泥技术, 2023, 1(4): 47-50.
GUO Yongqiang. Application Practice of ZGM113G Coal Mill Yield Improvement. Cement Technology, 2023, 1(4): 47-50.

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http://www.cemteck.com/CN/10.19698/j.cnki.1001-6171.20234047 或 http://www.cemteck.com/CN/Y2023/V1/I4/47

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[3]	LIU Yonggang, GAO Hongwei, XIAO Guiqing. Design Method of Road Structure Using Lean Concrete Base[J]. Cement Technology, 2018, 1(1): 27 -31 .
[4]	LIU Xu, LI Liang. Investigation of New Medium Temperature Wear-resistant Alloy Steel[J]. Cement Technology, 2018, 1(1): 32 -34 .
[5]	MA Debao. Finite Element Analysis of Inverted Cone in Raw Meal Silo[J]. Cement Technology, 2018, 1(1): 35 -38 .
[6]	HAN Zhongqi. [J]. Cement Technology, 2018, 1(1): 38 -48 .
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[9]	WEI Can, ZHANG Yuanyuan, AI Jun. Application of Cement Intelligent Control System in Overseas Projects[J]. Cement Technology, 2018, 1(1): 60 -64 .
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