水泥粉磨智能优化控制系统的应用

doi:10.19698/j.cnki.1001-6171.20193033

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摘要中材邦业（杭州）智能技术有限公司开发的水泥粉磨智能优化控制系统，采用一键启停技术、基于预测模型控制的先进控制技术和在线粒度分析仪，三者的有机结合，真正实现了水泥粉磨全过程、全工况、无人值守的自动化控制。水泥粉磨智能优化控制系统的实施，使系统能在最经济和最优化的参数下运行，系统启动时间由原来的10~15min缩短到5min，明显改善水泥磨系统工况，稳流仓波动的标准偏差降低70%以上，45μm筛筛余的标准偏差由0.97降低为0.75，比表面积合格率100%，三大主机设备平均电耗降低1.1kWh/t水泥。

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	魏灿
	俞利涛
	童睿
	王纯良

关键词: 水泥磨无人值守一键启停比表面积在线粒度分析仪

Abstract:

Intelligent optimization control system for cement grinding developed by the Sinoma & Bonyear (Hangzhou) Intelligent Technology Co., Ltd. adopts one-key start-stop technology, advanced control technology based on predictive model control and on-line particle size analyzer. The organic combination of the three realizes the automatic control of the whole process of cement grinding, all working conditions and unattended operation. The implementation of intelligent optimization control system for cement grinding enables the system to operate under the most economical and optimal parameters. The start-up time of the system is shortened from 10~15 minutes to 5 minutes, which improves the working condition of the cement grinding system. The standard deviation of the fluctuation of the stable flow silo is reduced by more than 70%. The standard deviation of residual sieve at 45 micron is reduced from 0.97 to 0.75. The qualified rate of the specific surface area is 100%, and the average power consumption of the three main equipments is reduced by 1.1 kWh/t .

Key words: cement mill unattended one key start-stop specific surface area xoptix on-line analyzer

收稿日期: 2018-12-10 出版日期: 2019-05-25 发布日期: 2019-05-29 整期出版日期: 2019-05-25

ZTFLH:

TQ172.632

引用本文:

魏灿, 俞利涛, 童睿, 王纯良.

水泥粉磨智能优化控制系统的应用

[J]. 水泥技术, 2019, 1(3): 33-39.
WEI Can, YU Litao, TONG Rui, WANG Chunliang. Application of Intelligent Optimal Control System for Cement Grinding. Cement Technology, 2019, 1(3): 33-39.

链接本文:

http://www.cemteck.com/CN/10.19698/j.cnki.1001-6171.20193033 或 http://www.cemteck.com/CN/Y2019/V1/I3/33

[1]	蔡文举. 比表面积测试仪的影响因素及校正方法 [J]. 水泥技术, 2019, 1(4): 49-52.
[2]	杜鑫, 宋留庆, 贺孝一, 豆海建, 秦中华, 张明飞, 王维莉. 不同混合材对水泥辊磨产品比表面积的影响 [J]. 水泥技术, 2018, 1(5): 68-72.
[3]	杨瑞海, 陆文雄, 余淑华, 李柯, 李小亮. 高效矿渣复合助磨剂的试验研究 [J]. 水泥技术, 2008, 1(2): 75-78.
[4]	高阳, 李健生, 霍碧莉. 不同助磨剂对水泥粉磨效率的影响 [J]. 水泥技术, 2005, 1(3): 69-71.
[5]	高阳, 李健生, 霍碧莉. 不同助磨剂对水泥粉磨效率的影响[J]. 水泥技术, 2004, 1(6): 30-32.
[6]	韩仲琦. 水泥粒度的表征与评价[J]. 水泥技术, 2002, 1(增刊): 3-6.
[7]	赵东镐, 王雪晶. 增钙渣和混合材与水泥比表面积的关系[J]. 水泥技术, 2001, 1(5): 66-68.

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[2]	LIU Yonggang, GAO Hongwei, XIAO Guiqing. Design Method of Road Structure Using Lean Concrete Base[J]. Cement Technology, 2018, 1(1): 27 -31 .
[3]	MA Debao. Finite Element Analysis of Inverted Cone in Raw Meal Silo[J]. Cement Technology, 2018, 1(1): 35 -38 .
[4]	HAN Zhongqi. [J]. Cement Technology, 2018, 1(1): 38 -48 .
[5]	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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